KR101168515B1 - Subrack - Google Patents

Abstract

The present invention relates to a sub-rack including a sub-rack body having a mounting space for mounting a substrate, and a guide having a fixing protrusion formed to protrude toward an insertion groove for fixing the substrate.
According to the present invention, it is possible to safely protect the substrates from the external force generated by the earthquake or the like by improving the anti-vibration.

Description

Subrack

The present invention relates to a subrack for mounting a substrate used in an electronic communication device.

In general, substrates having various functions are used in electronic communication devices such as general purpose computers, digital switching systems, and large-capacity monitoring and control devices. For example, a substrate for a communication module, a substrate for an I / O module, a substrate for a power module, or the like may be used. These substrates are mounted inside the subrack. The subracks protect the substrates from foreign debris, external shocks, and the like. The subrack according to the prior art has the following problems.

First, there is a problem in that the subrack according to the prior art cannot safely protect the substrates from external force generated by an earthquake or the like. That is, the subrack according to the prior art has a problem that the dust resistance is not excellent. Therefore, the subrack according to the prior art has a problem that can not be applied to safety-critical equipment such as nuclear power plants.

Second, in the subrack according to the prior art, electromagnetic waves may pass in and out between the inside and the outside where the substrate is mounted. Accordingly, the subrack according to the related art does not protect the substrates and other electronic communication devices located outside the sub rack from electromagnetic waves.

Third, heat is generated in the process of operating the substrates. The subrack according to the prior art does not dissipate heat generated from the substrates, so that the temperature of the mounting space in which the substrates are mounted increases. There is a problem that does not work properly.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a subrack that can safely protect substrates from external forces generated by an earthquake or the like by improving anti-vibration.

Another object of the present invention is to provide a subrack capable of blocking the entry of electromagnetic waves to protect substrates mounted inside the subrack and other electronic communication devices located outside the subrack from electromagnetic waves.

Another object of the present invention is to provide a subrack capable of dissipating heat generated as the substrates are operated in order to maintain the mounting space in which the substrates are mounted in a temperature range in which the substrates can be operated normally.

In order to achieve the above-mentioned object, the present invention can include the following configuration.

Subrack according to the present invention is a sub-rack body formed with a mounting space for mounting a substrate; And a guide part installed on the sub rack body and into which the substrate mounted on the sub rack body is inserted. The guide part may include an insertion groove for inserting the substrate, and a fixing protrusion formed to protrude toward the insertion groove so that the width of the insertion groove is reduced to fix the substrate inserted into the insertion groove.

Subrack according to the present invention is a sub-rack body formed with a mounting space for mounting a substrate; A guide part installed in the sub rack body and into which the substrate mounted on the sub rack body is inserted; And a connection member installed in the sub rack body and electrically connected to the substrate inserted into the guide part to ground the substrate inserted into the guide part.

According to the present invention, the following effects can be achieved.

The present invention can safely protect the substrates from external forces generated by earthquakes and the like by improving the anti-vibration, thereby extending the scope of application for safety-critical equipment such as nuclear power plants.

The present invention can block electromagnetic waves from entering and exiting a subrack, thereby protecting substrates mounted inside the subrack and other electronic communication devices located outside the subrack from electromagnetic waves.

The present invention can dissipate heat generated as the substrates are operated, thereby preventing the temperature of the mounting space in which the substrates are mounted rises above a temperature range in which the substrates can be normally operated.

1 is a schematic perspective view of a subrack according to the invention
2 is a schematic plan view of a guide unit according to the present invention;
Figure 3 is a schematic plan view of the lower guide portion according to the present invention
Figure 4 is a schematic plan view of the upper guide portion according to the present invention
5 is a schematic perspective view of a sub rack body according to the present invention;
Figure 6 is a schematic exploded perspective view of the bottom plate of the sub-rack body according to the present invention
7 is a schematic exploded perspective view of a top plate of the sub-rack body according to the present invention;
8 is a schematic perspective view illustrating a coupling relationship between a first side plate and a first electromagnetic shielding member according to the present invention;
9 is a schematic plan view of a sub rack body according to the present invention and a schematic plan cross-sectional view of a first electromagnetic shielding member and a second electromagnetic shielding member;
10 is a schematic perspective view of a cover member according to the present invention;
11 is a schematic perspective view of a lower connection member and a lower ground member according to the present invention;
12 is a schematic perspective view of the upper connection member and the upper ground member according to the present invention;
13 is a schematic perspective view of a fixing groove of the sub-rack body according to the present invention

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the subrack according to the present invention will be described in detail.

Referring to FIG. 1, a sub rack 1 according to the present invention includes a guide part 2 into which a substrate 10 is inserted, and a sub rack body 3 in which the guide part 2 is installed. As the substrate 10 is inserted into the guide part 2, the substrate 10 is mounted on the subrack body 3. The subrack body 3 includes a mounting space 3a for mounting the substrate 10. At least one substrate 10 may be mounted on the subrack body 3. The sub rack body 3 may include a mounting space 3a formed in a size in which the plurality of substrates 10 may be installed. The substrate 10 may be separated from the sub-rack body 3 as necessary. Hereinafter, the guide unit 2 and the subrack body 3 will be described in detail with reference to the accompanying drawings.

1 and 2, the guide part 2 is installed in the sub rack body 3. The subrack 1 according to the present invention may include a plurality of the guide parts 2. The guide portions 2 are perpendicular to the direction in which the substrate 10 is mounted to the sub-rack body 3 or moved to be separated from the sub-rack body 3 (in the direction of the X arrow, FIG. 1). It may be installed in the sub-rack body (3) spaced apart from each other by a predetermined distance.

The guide part 2 may include an insertion groove 2a. The substrate 10 is inserted into the insertion groove 2a. The insertion groove 2a may be elongated in a direction in which the substrate 10 is moved in order to be mounted on the sub rack body 3 or to be separated from the sub rack body 3.

The guide part 2 may include a fixing protrusion 2b formed to protrude toward the insertion groove 2a. The portion where the fixing protrusion 2b is formed in the insertion groove 2a is formed to have a smaller width H than the other portion by the fixing protrusion 2b. The portion where the fixing protrusion 2b is formed in the insertion groove 2a may be formed to have a width H that substantially corresponds to the width T of the substrate 10. Accordingly, when the substrate 10 is inserted into the guide part 2, the substrate 10 may be fixed by the fixing protrusion 2b. Therefore, the subrack 1 according to the present invention can be secured by fixing the substrate 10 so as not to be shaken by an external force generated by an earthquake. That is, the subrack 1 according to the present invention can be improved in the vibration resistance by the fixing protrusion (2b), and thus can be applied to safety-critical equipment such as nuclear power plants. The guide part 2 may include a plurality of fixing protrusions 2b. Therefore, the subrack 1 according to the present invention can more firmly fix the substrate 10. The fixing protrusions 2b may be formed to be spaced apart from each other by a predetermined distance.

The fixing protrusion 2b may be formed at a position spaced a predetermined distance from the inlet of the insertion groove 2a for inserting the substrate 10. Thus, when the substrate 10 is inserted into the insertion groove (2a), the substrate 10 is inserted into the insertion groove (2a) through the entrance formed in a relatively large width in the insertion groove (2a) Can be. Therefore, the substrate 10 can be easily mounted on the subrack 1 according to the present invention. The fixing protrusion 2b may be formed to have a size diminishing in a direction protruding toward the insertion groove 2a. The fixing protrusion 2b may be formed to protrude from a curved surface as a whole. Accordingly, the substrate 10 may be guided to be mounted at the correct position in the sub rack body 3 while passing through the fixing protrusion 2b.

1 and 3, the guide part 2 may include a lower guide part 21 into which a lower part of the substrate 10 is inserted. The lower guide part 21 is installed in the sub rack body 3. The subrack 1 according to the present invention may include a plurality of lower guide parts 21. The lower guide portions 21 are perpendicular to the direction in which the substrate 10 is moved to be mounted on or separated from the sub-rack body 3 (X arrow direction, FIG. 1). It may be installed in the sub-rack body (3) spaced apart from each other by a predetermined distance.

The lower guide part 21 may include a lower insertion groove 211. The lower portion of the substrate 10 is inserted into the lower insertion groove 211. The lower insertion groove 211 may be elongated in a direction in which the substrate 10 is moved to be mounted on the sub rack body 3 or separated from the sub rack body 3.

The lower guide part 21 may include a lower fixing protrusion 212 formed to protrude toward the lower insertion groove 211. The portion of the lower fixing protrusion 212 formed in the lower insertion groove 211 is formed by the lower fixing protrusion 212 has a smaller width (H1) than other portions. A portion where the lower fixing protrusion 212 is formed in the lower insertion groove 211 may be formed to have a width H1 substantially coincident with the lower width T1 of the substrate 10. Accordingly, when the substrate 10 is inserted into the lower guide part 21, the substrate 10 may be fixed by the lower fixing protrusion 212. Therefore, the subrack 1 according to the present invention can be secured by fixing the substrate 10 so as not to be shaken by an external force generated by an earthquake. That is, the subrack 1 according to the present invention can be improved in the tojinjin by the lower fixing projections (212). The lower guide part 21 may include a plurality of lower fixing protrusions 212. Therefore, the subrack 1 according to the present invention can more firmly fix the substrate 10. The lower fixing protrusions 212 may be formed to be spaced apart from each other by a predetermined distance.

The lower fixing protrusion 212 may be formed at a position spaced a predetermined distance from the inlet of the lower insertion groove 211 for inserting the substrate 10. Accordingly, when the substrate 10 is inserted into the lower insertion groove 211, the lower portion of the substrate 10 passes through an inlet formed with a relatively large width in the lower insertion groove 211 and the lower insertion groove. It can be inserted into (211). Therefore, the substrate 10 can be easily mounted on the subrack 1 according to the present invention. The lower fixing protrusion 212 may be formed in a shape that is reduced in size in a direction protruding toward the lower insertion groove 211. The lower fixing protrusion 212 may be formed to protrude in a curved shape as a whole. Accordingly, the substrate 10 may be guided to be mounted at the correct position in the sub-rack body 3 while passing through the lower fixing protrusion 212.

1 and 3, when the sub rack 1 according to the present invention includes a plurality of lower guide parts 21, the lower fixing protrusions 221 a and 221 b are disposed on the substrates 10 a and 10 b. Therefore, it may be formed to protrude to different length (L1, L2). That is, the lower guide portions 21a and 21b have lower insertion grooves 211a and 211b having different widths H1 and H2 according to the substrates 10a and 10b by the lower fixing protrusions 221a and 221b. Can include them. Lower widths T1 and T2 of the substrates 10a and 10b may be formed in different sizes according to functions of the substrates 10a and 10b. Accordingly, the sub-rack 1 according to the present invention may be disposed on the lower guide portions 21a and 21b having the widths H1 and H2 corresponding to the lower widths T1 and T2 of the substrates 10a and 10b. The substrates 10a and 10b may be mounted. In addition, the sub rack 1 according to the present invention has a width (H1, H2) of the lower insertion groove (211a, 211b) by the lower fixing projections (221a, 221b), and the substrate (10a, 10b) By comparing the sizes of the lower widths T1 and T2, the positions at which the substrates 10a and 10b should be mounted can be distinguished, thereby improving the ease of operation for mounting the substrates 10a and 10b. .

For example, the first lower guide part 21a of the lower guide parts 21 may include a first lower fixing protrusion 221a protruding toward the first lower insertion groove 211a at a first length L1. Can be. Accordingly, the first lower insertion groove 211a may be formed to have a first width H1. The second lower guide part 21b of the lower guide parts 21 may include a second lower fixing protrusion 221b formed to protrude toward the second lower insertion groove 211b at a second length L2. . Accordingly, the second lower insertion groove 211b may be formed to have a second width H2. The first length L1 and the second length L2 are different lengths. Accordingly, the substrate 10a having the lower width T1 corresponding to the first width H1 may be inserted into the first lower guide part 21a and the second lower guide part 21b. The substrate 10b having the lower width T2 corresponding to the second width H2 may be inserted.

1 and 3, the lower guide portions 21a and 21b may include lower insertion grooves 211a and 211b formed in different shapes according to the substrates 10a and 10b. The lower shapes of the substrates 10a and 10b may be formed in different shapes according to the functions of the substrates 10a and 10b. The lower insertion grooves 211a and 211b include lengths L1 and L2 in which the lower fixing protrusions 221a and 221b protrude toward the lower insertion grooves 211a and 211b and the lower fixing protrusions 221a and 221b. It may have a different shape according to the shape having, the number of the lower fixing projections (221a, 221b) is formed. Although not shown, a plurality of lower fixing protrusions 212 may be formed to protrude to different lengths in one lower insertion groove 211. Accordingly, the sub rack 1 according to the present invention allows the substrates 10a and 10b to be mounted on the lower guide portions 21a and 21b having shapes corresponding to the lower shapes of the substrates 10a and 10b. Can be. In addition, the sub rack 1 according to the present invention is to be mounted on the substrate (10a, 10b) by comparing the shape of the lower insertion grooves (211a, 211b) and the lower shape of the substrate (10a, 10b) Since the positions can be distinguished, the ease of operation for mounting the substrates 10a and 10b can be improved. For example, the first lower guide part 21a of the lower guide parts 21 may include a first lower insertion groove 211a formed in a shape corresponding to the lower part of the first substrate 10a. The second lower guide part 21b of the lower guide parts 21 may include a second lower insertion groove 211b formed in a shape corresponding to the lower part of the second substrate 10b. The second lower insertion groove 211b has a different shape from the first lower insertion groove 211a. The first substrate 10a and the second substrate 10b may have different functions.

1 and 4, the guide part 2 may include an upper guide part 22 into which an upper part of the substrate 10 is inserted. The upper guide part 22 is installed in the sub rack body 3. The upper guide part 22 may be installed in the sub rack body 3 to be positioned above the lower guide part 21. The subrack 1 according to the present invention may include a plurality of the upper guide portion 22. The upper guide portions 22 are mutually perpendicular to the direction in which the substrate 10 is moved to be mounted on or separated from the sub-rack body 3 (X arrow direction). The subrack body 3 may be spaced apart by a predetermined distance.

The upper guide portion 22 may include an upper insertion groove 221. The upper portion of the substrate 10 is inserted into the upper insertion groove 221. The upper insertion groove 221 may be elongated in a direction in which the substrate 10 is moved to be mounted on the sub rack body 3 or separated from the sub rack body 3.

The upper guide part 22 may include an upper fixing protrusion 222 formed to protrude toward the upper insertion groove 221. A portion of the upper fixing protrusion 222 formed in the upper insertion groove 221 is formed to have a smaller width (H3) than the other portion by the upper fixing protrusion 222. A portion where the upper fixing protrusion 222 is formed in the upper insertion groove 221 may be formed to have a width H3 substantially equal to the upper width T3 of the substrate 10. Accordingly, when the substrate 10 is inserted into the upper guide portion 22, the substrate 10 may be fixed by the upper fixing protrusion 222. Therefore, the subrack 1 according to the present invention can be secured by fixing the substrate 10 so as not to be shaken by an external force generated by an earthquake. That is, the sub-rack 1 according to the present invention can be improved in the anti-vibration by the upper fixing protrusion 222, it can be applied to safety-critical equipment such as nuclear power plants. The upper guide part 22 may include a plurality of upper fixing protrusions 222. Therefore, the subrack 1 according to the present invention can more firmly fix the substrate 10. The upper fixing protrusions 222 may be formed spaced apart from each other by a predetermined distance. The upper width T3 and the lower width T1 of FIG. 3 may be formed in the same size or may be formed in different sizes.

The upper fixing protrusion 222 may be formed at a position spaced a predetermined distance from the inlet of the upper insertion groove 221 for the substrate 10 is inserted. Accordingly, when the substrate 10 is inserted into the upper insertion groove 221, the upper portion of the substrate 10 passes through an entrance formed with a relatively large width in the upper insertion groove 221 and the upper insertion groove. 221 may be inserted. Therefore, the substrate 10 can be easily mounted on the subrack 1 according to the present invention. The upper fixing protrusion 222 may be formed in a shape that is reduced in size in a direction protruding toward the upper insertion groove 221. The upper fixing protrusion 222 may be formed to protrude to form a curved surface as a whole. Accordingly, the substrate 10 may be guided to be mounted at the correct position in the sub-rack body 3 while passing through the upper fixing protrusion 222.

1 and 4, when the sub rack 1 according to the present invention includes a plurality of the upper guide parts 22, the upper fixing protrusions 222a and 222b are disposed on the substrates 10a and 10b. Therefore, it may be formed to protrude to different length (L3, L4). That is, the upper guide portions 22a and 22b have upper insertion grooves 221a and 221b having different widths H3 and H4 depending on the substrates 10a and 10b by the upper fixing protrusions 222a and 222b. Can include them. Upper widths T3 and T4 of the substrates 10a and 10b may be formed in different sizes according to functions of the substrates 10a and 10b. Accordingly, the sub-rack 1 according to the present invention has the upper guide portions 22a and 22b having the widths H3 and H4 corresponding to the upper widths T3 and T4 of the substrates 10a and 10b. The substrates 10a and 10b may be mounted. In addition, the sub rack 1 according to the present invention is the width (H3, H4) of the upper insertion grooves (221a, 221b) by the upper fixing projections (222a, 222b), and the substrate (10a, 10b) By comparing the sizes of the upper widths (T3, T4) of the position where the substrate (10a, 10b) should be mounted can be distinguished, it is possible to improve the ease of operation for mounting the substrate (10a, 10b) .

For example, the first upper guide part 22a of the upper guide parts 22 may include a first upper fixing protrusion 222a protruding toward the first upper insertion groove 221a at a first length L3. Can be. Accordingly, the first upper insertion groove 221a may be formed to have a first width H3. The second upper guide part 22b of the upper guide parts 22 may include a second upper fixing protrusion 222b formed to protrude toward the second upper insertion groove 221b at a second length L4. . Accordingly, the second upper insertion groove 221b may be formed to have a second width H4. The first length L3 and the second length L4 are different lengths. Accordingly, the substrate 10a having the upper width T3 corresponding to the first width H3 may be inserted into the first upper guide part 22a and the second upper guide part 22b. The substrate 10b having the upper width T4 corresponding to the second width H4 may be inserted.

1 and 4, the upper guide parts 22a and 22b may include upper insertion grooves 221a and 221b formed in different shapes according to the substrates 10a and 10b. The upper shapes of the substrates 10a and 10b may be formed in different shapes according to the functions of the substrates 10a and 10b. The upper insertion grooves 221a and 221b may include lengths L3 and L4 in which the upper fixing protrusions 222a and 222b protrude toward the upper insertion grooves 221a and 221b and the upper fixing protrusions 222a and 222b. It may be formed in a different form according to the shape having, the number of the upper fixing protrusions (222a, 222b) is formed. Although not shown, a plurality of upper fixing protrusions 222 may be formed to protrude to different lengths in one upper insertion groove 221. Accordingly, the sub rack 1 according to the present invention allows the substrates 10a and 10b to be mounted on the upper guide portions 22a and 22b having shapes corresponding to the upper shapes of the substrates 10a and 10b. Can be. In addition, the sub rack 1 according to the present invention is to be mounted on the substrate (10a, 10b) by comparing the shape of the upper insertion grooves (221a, 221b), and the upper shape of the substrate (10a, 10b) Since the positions can be distinguished, the ease of operation for mounting the substrates 10a and 10b can be improved. For example, the first upper guide part 22a of the upper guide parts 22 may include a first upper insertion groove 221a formed in a shape corresponding to the upper part of the first substrate 10a. The second upper guide part 22b of the upper guide parts 22 may include a second upper insertion groove 221b formed in a shape corresponding to the upper part of the second substrate 10b. The second upper insertion groove 221b has a different shape from the first upper insertion groove 221a. The first substrate 10a and the second substrate 10b may have different functions.

1 and 5, the subrack body 3 is provided with the guide part 2. At least one of the lower guide part 21 and the upper guide part 22 may be installed in the sub rack body 3. The subrack body 3 includes a mounting space 3a for mounting the substrate 10. The sub rack body 3 may include a lower plate 31, an upper plate 32, a rear plate 33, and a side plate. The bottom plate 31, the top plate 32, the back plate 33, and the side plate may be detachably coupled to each other.

The lower guide part 21 may be installed on the lower plate 31. A plurality of lower guide parts 21 may be installed on the lower plate 31. The lower plate 31 may form a lower surface of the sub rack body 3.

5 and 6, the lower plate 31 has a lower heat dissipation plate 311 for dissipating heat generated in the mounting space 3a, and the mounting space 3a and the mounting space 3a. It may include a lower electromagnetic shielding filter 312 for blocking the electromagnetic wave coming in and out between the outside.

The lower heat dissipation plate 311 includes a plurality of lower vent holes for dissipating heat generated in the mounting space 3a. The lower vent holes may be spaced apart from each other by a predetermined distance. The lower vent holes may communicate the mounting space 3a with the outside of the subrack body 3. Accordingly, heat generated in the mounting space 3a may be discharged to the lower side of the sub-rack body 3 through the lower vent holes. Therefore, the sub-rack 1 according to the present invention by heat dissipation generated by the operation of the substrate 10, the temperature of the mounting space (3a) is more than the temperature range that the substrate 10 can operate normally Can be prevented from rising. Accordingly, the subrack 1 according to the present invention can be applied to the safety-critical equipment such as nuclear power plants by allowing the substrate 10 to operate stably while exhibiting the original functions.

The lower electromagnetic shielding filter 312 blocks electromagnetic waves from entering and exiting through the lower heat sink 311. Accordingly, the subrack 1 according to the present invention can protect the substrate 10 mounted inside the sub rack body 3 and other electronic communication devices located outside the sub rack body 3 from electromagnetic waves. The lower electromagnetic shielding filter 312 may be formed of a metal material to block electromagnetic waves from entering and exiting, for example, may be formed of aluminum. The lower electromagnetic shielding filter 312 may be formed in a mesh form in which a plurality of lower shielding holes 3121 are formed. When the electromagnetic wave passes through the lower shielding holes 3121, the electromagnetic wave may be offset or absorbed by mutual energy interaction (collision) between the electrons. Accordingly, the lower electromagnetic shielding filter 312 may block the electromagnetic wave from entering and exiting between the mounting space 3a and the outside of the subrack body 3 through the lower heat dissipation plate 311. In addition, the lower electromagnetic shielding filter 312 may radiate heat generated in the mounting space 3a through the lower shielding holes 3121. Therefore, the sub-rack 1 according to the present invention can radiate heat generated in the mounting space 3a, and at the same time, the electromagnetic wave enters and exits in the process of radiating heat generated in the mounting space 3a. You can block. The lower shielding hole 3121 may be formed to have a hexagonal cross section as shown in an enlarged view of FIG. 6.

5 and 6, the lower plate 31 may include a plurality of lower heat sinks 311. For example, the lower plate 31 may include a first lower heat sink 311a and a second lower heat sink 311b. A plurality of first lower through holes 3111a are formed in the first lower heat dissipation plate 311a, and a plurality of second lower through holes 3111b are formed in the second lower heat dissipation plate 311b. The lower electromagnetic shielding filter 312 may be located between the first lower heat sink 311a and the second lower heat sink 311b. That is, the lower electromagnetic shielding filter 312 may be disposed below the first lower heat shielding plate 311a, and the second lower thermal shielding plate 311b may be positioned below the lower electromagnetic shielding filter 312. In this case, the lower guide part 21 may be installed in the first lower heat radiation plate 311a. When a plurality of lower guide parts 21 are installed in the first lower heat dissipation plate 311a, the first lower through holes 3111a may be formed in spaces in which the lower guide parts 21 are spaced apart from each other. have. Although not shown, the lower plate 31 may include a plurality of lower electromagnetic shielding filters 312.

5 and 7, the upper guide part 22 may be installed on the upper plate 32. A plurality of upper guide parts 22 may be installed on the upper plate 32. The upper plate 32 may form an upper surface of the sub rack body 3. The top plate 32 is an upper heat dissipation plate 321 for dissipating heat generated in the mounting space (3a), and to block the electromagnetic wave coming in and out between the mounting space (3a) and the outside of the mounting space (3a). It may include an upper electromagnetic shielding filter 322 for.

The upper heat dissipation plate 321 includes a plurality of upper vent holes for dissipating heat generated in the mounting space 3a. The upper vent holes may be formed to be spaced apart from each other by a predetermined distance. The upper vent holes may communicate the mounting space 3a with the outside of the subrack body 3. Accordingly, heat generated in the mounting space 3a may be discharged to the upper side of the sub rack body 3 through the upper vent holes. Therefore, the sub-rack 1 according to the present invention by heat dissipation generated by the operation of the substrate 10, the temperature of the mounting space (3a) is more than the temperature range that the substrate 10 can operate normally Can be prevented from rising. Accordingly, the subrack 1 according to the present invention can be applied to the safety-critical equipment such as nuclear power plants by allowing the substrate 10 to operate stably while exhibiting the original functions.

The upper electromagnetic shielding filter 322 blocks electromagnetic waves from entering and exiting through the upper heat sink 321. Accordingly, the subrack 1 according to the present invention can protect the substrate 10 mounted inside the sub rack body 3 and other electronic communication devices located outside the sub rack body 3 from electromagnetic waves. The upper electromagnetic shielding filter 322 may be formed of a metal material to block electromagnetic waves from entering and exiting, for example, may be formed of aluminum. The upper electromagnetic shielding filter 322 may be formed in a mesh form in which a plurality of upper shielding holes 3221 are formed. When the electromagnetic wave passes through the upper shielding holes 3221, the electromagnetic wave may be offset or absorbed by mutual energy interaction (collision) between the electrons. Accordingly, the upper electromagnetic shielding filter 322 may block the electromagnetic wave from entering and leaving between the mounting space 3a and the outside of the subrack body 3 through the upper heat dissipation plate 321. In addition, the upper electromagnetic shielding filter 322 may radiate heat generated in the mounting space 3a through the upper shielding holes 3221. Therefore, the sub-rack 1 according to the present invention can radiate heat generated in the mounting space 3a, and at the same time, the electromagnetic wave enters and exits in the process of radiating heat generated in the mounting space 3a. You can block. The upper shielding hole 3221 may be formed to have a hexagonal cross section as shown in the enlarged view of FIG. 7.

5 and 7, the top plate 32 may include a plurality of upper heat sinks 321. For example, the top plate 32 may include a first top heat sink 321a and a second top heat sink 321b. A plurality of first upper through holes 3211a are formed in the first upper heat dissipation plate 321a, and a plurality of second upper through holes 3211b are formed in the second upper heat dissipation plate 321b. The upper electromagnetic shielding filter 322 may be positioned between the first upper heat sink 321a and the second upper heat sink 321b. That is, the upper electromagnetic shielding filter 322 may be disposed on the upper side of the first upper heat shielding plate 321a, and the second upper radiating plate 321b may be disposed on the upper side of the upper electromagnetic shielding filter 322. In this case, the upper guide part 22 may be installed in the first upper heat dissipation plate 321a. When the plurality of upper guide parts 22 are installed in the first upper heat dissipation plate 321a, the first upper through holes 3211a may be formed in the spaces in which the upper guide parts 22 are spaced apart from each other. have. Although not shown, the top plate 32 may include a plurality of upper electromagnetic shielding filters 322.

5 to 7, the back plate 33 is coupled to the bottom plate 31, the top plate 32, and the side plate. The back plate 33 may form a rear surface of the sub rack body 3. The sub rack body 3 may include a heat dissipation space 3b formed on the opposite side of the mounting space 3a based on the connection substrate 100 to which the substrate 10 is connected. The connecting substrate 100 is installed between the front surface and the rear surface of the sub-rack body 3. That is, the back plate 33 is positioned spaced apart from the connecting substrate 100 to which the substrate 10 is connected. The connection substrate 100 includes a plurality of connection vent holes 101 for communicating the mounting space 3a and the heat dissipation space 3b. Accordingly, heat generated in the mounting space 3a may be discharged into the heat dissipation space 3b through the connection vent holes 101. Therefore, the sub-rack 1 according to the present invention by heat dissipation generated by the operation of the substrate 10, the temperature of the mounting space (3a) is more than the temperature range that the substrate 10 can operate normally Can be prevented from rising. Accordingly, the subrack 1 according to the present invention can be applied to the safety-critical equipment such as nuclear power plants by allowing the substrate 10 to operate stably while exhibiting the original functions. The connection substrate 100 may include at least one slot 102, and the substrate 10 may be inserted into and electrically connected to the slot 102. The connection vent holes 101 may be formed in the remaining area except the area in which the slots 102 are installed. The connection vent holes 101 may be formed above the intermediate point with reference to an intermediate point with respect to the length of the connection board 100 in the vertical direction (Y arrow direction). Although not shown, the back plate 33 may include a plurality of back vents. The back vents may communicate the heat dissipation space 3b with the outside of the subrack body 3. Accordingly, heat generated in the mounting space 3a may be discharged to the rear side of the sub-rack body 3 through the connection vent 101, the heat dissipation space 3b, and the back vent.

Referring to FIG. 5, the side plate is coupled to the bottom plate 31, the top plate 32, and the back plate 33. The side plate may include a first side plate 34 constituting one side of the sub rack body 3, and a second side plate 35 constituting the other side of the sub rack body 3. The first side plate 34 may form the left side of the subrack body 3, and the second side plate 35 may form the right side of the subrack body 3.

1, 8, and 9, the sub rack 1 according to the present invention may further include an electromagnetic shielding member 4 (shown in FIG. 9). The electromagnetic shielding member 4 is coupled to the side plate to shield electromagnetic waves. The side plate may include an installation member protruding to correspond to the electromagnetic shielding member (4). The electromagnetic shielding member 4 may be coupled to the installation member. The substrate 10 may be mounted to the sub-rack body 3 while being coupled to the front plate 20 (shown in FIG. 1). The substrate 10 may be mounted on the sub rack body 3 as the front plate 20 is coupled to the sub rack body 3. The substrate 10 may be separated from the sub rack body 3 as the front plate 20 is separated from the sub rack body 3. The electromagnetic shielding member 4 may shield a gap between the side plate and the front plate 20 (shown in FIG. 1). Accordingly, the subrack 1 according to the present invention can protect the substrate 10 mounted inside the sub rack body 3 and other electronic communication devices located outside the sub rack body 3 from electromagnetic waves. A plurality of front plates 20, 20 ′, 20 ″, shown in FIG. 1 may be coupled to the subrack body 3. The front plates 20, 20 ′, 20 ″ may be coupled to the substrate 10. ) May be mounted adjacent to each other in the direction (X arrow direction) perpendicular to the direction in which it is mounted to the sub-rack body 3 or moved to be separated from the sub-rack body 3.

The electromagnetic shielding member 4 may include a first electromagnetic shielding member 41. The first electromagnetic shielding member 41 is coupled to the first side plate 34. The first electromagnetic shielding member 41 shields a gap between the first side plate 34 and the first front plate 20a (shown in FIG. 8) positioned adjacent to the first side plate 34. can do. The first electromagnetic shielding member 41 may be formed of a material having low contact resistance and excellent shielding effect against electromagnetic waves. For example, the first electromagnetic shielding member 41 may be formed of Phosphor Bronze, Beryllium Bronze, or the like.

1, 8, and 9, the installation member may include a first installation member 341 for coupling the first electromagnetic shielding member 41. The first installation member 341 may be formed to protrude from the first side plate 34. The first installation member 341 may be formed to protrude in a direction (A arrow direction) toward the rear plate 33 from the first front plate 20a coupled to the sub-rack body 3. The first installation member 341 may be formed to protrude from the first side plate 34 in a vertical direction (Y arrow direction). The first installation member 341 may be formed long in the vertical direction (Y arrow direction).

The first electromagnetic shielding member 41 may include a first insertion member 411. The first installation member 341 may be inserted into the first insertion member 411. The first electromagnetic shielding member 41 may be coupled to the first side plate 34 by inserting the first installation member 341 into the first insertion member 411. The first insertion member 411 may include a first fixing member 4111 and a first moving member 4112.

The first fixing member 4111 may be in contact with one surface 341a of the first installation member 341. One surface 341a of the first mounting member 341 may be a surface opposite to the other surface 341b of the first mounting member 341. The other surface 341b of the first mounting member 341 may be a surface facing the first front plate 20a positioned adjacent to the first side plate 34.

The first moving member 4112 may be in contact with the other surface 341b of the first installation member 341. That is, the first installation member 341 may be inserted between the first moving member 4112 and the first fixing member 4111. The first fixing member 4112 is configured to move the first mounting member 341 in a direction close to the first fixing member 4111 after the first installation member 341 is inserted into the first insertion member 411. It can be elastically connected to (4111). That is, the first moving member 4112 may be connected to the first fixing member 4111 to have an elastic force in a direction closer to the first fixing member 4111. Accordingly, the first moving member 4112 exerts a force on the other surface 341b of the first mounting member 341 by an elastic force, so that the first electromagnetic shielding member 41 is formed by the first mounting member ( 341) can be rigidly coupled.

1 and 9, the other surface 341b of the first installation member 341 is increased in size as the first installation member 341 faces the direction in which the first installation member 341 is inserted into the first insertion member 411. This can be formed to be inclined. Therefore, in the process in which the substrate 10 is mounted on the sub-rack body 3 or the substrate 10 is separated from the sub-rack body 3, the sub-rack 1 according to the present invention is the first rack The electromagnetic shielding member 41 can be prevented from being easily separated from the first installation member 341. The first electromagnetic shielding member 41 is removed from the first mounting member 341 only when an external force that can open the first insertion member 411 is applied to the maximum size of the first mounting member 341. Because it can be separated. In addition, the sub-rack 1 according to the present invention can be prevented from being separated from the first mounting member 341 by the external force generated by the earthquake or the like.

1 and 9, a first locking groove 3411 may be formed on the other surface 341b of the first installation member 341. The first moving member 4112 may include a first locking protrusion 4112a to be inserted into the first locking groove 3411. When the first electromagnetic shielding member 41 is coupled to the first installation member 341, the first catching protrusion 4112a is inserted into the first catching groove 3411. Since the first locking projection 4112a is inserted into the first locking groove 3411, the first electromagnetic shielding member 41 may be prevented from being easily separated from the first installation member 341 by the locking. have.

1, 8, and 9, the first electromagnetic shielding member 41 may include a first shielding member 412. The first shielding member 412 is supported by the first front plate 20a positioned adjacent to the first side plate 34 so that the first side plate 34 and the first front plate 20a are supported. The gap between the liver can be shielded. The first shielding member 412 may be elastically connected to the first fixing member 4111 to be supported by the first front plate 20a. That is, the first shielding member 412 may be connected to the first fixing member 4111 to have an elastic force in a direction away from the other surface 341b of the first installation member 341. Accordingly, the first shielding member 412 may apply a force to the first front plate 20a by an elastic force. Therefore, the first electromagnetic shielding member 41 can more completely block the movement of electromagnetic waves through the gap between the first side plate 34 and the first front plate 20a.

Referring to FIG. 8, a plurality of first electromagnetic shielding members 41 may be coupled to the first installation member 341. The first electromagnetic shielding members 41 may be coupled to the first mounting member 341 adjacent to each other in a vertical direction (Y arrow direction) in which the first mounting member 341 is formed to protrude. As shown in FIG. 8, a plurality of first electromagnetic shielding members 41 may be formed in a plurality of first electromagnetic shielding members 41 in a length direction (Y arrow direction) of the first installation member 341. Accordingly, the number of operations for coupling the first electromagnetic shielding members 41 to the first installation member 341 can be reduced. The first electromagnetic shielding member 41 may be formed to be connected in plural to a length corresponding to the length of the first installation member 341. Accordingly, the first electromagnetic shielding members 41 may be coupled to the first installation member 341 in one operation.

1 and 9, the electromagnetic shielding member 4 may further include a second electromagnetic shielding member 42. The second electromagnetic shielding member 42 is coupled to the second side plate 35. The second electromagnetic shielding member 42 shields a gap between the second side plate 35 and the second front plate 20b (shown in FIG. 8) positioned adjacent to the second side plate 35. can do. The second electromagnetic shielding member 42 may be formed of a material having low contact resistance and excellent shielding effect against electromagnetic waves. For example, the second electromagnetic shielding member 42 may be formed of phosphor bronze, beryllium copper, or the like.

1 and 9, the installation member may include a second installation member 351 to which the second electromagnetic shielding member 42 is coupled. The second installation member 351 may be formed to protrude from the second side plate 35. The second installation member 351 may be formed to protrude in a direction (A arrow direction) toward the rear plate 33 from the second front plate 20b coupled to the sub-rack body 3. The second installation member 351 may be formed to protrude from the second side plate 35 in a vertical direction (Y arrow direction). The second installation member 351 may be formed long in the vertical direction (Y arrow direction).

The second electromagnetic shielding member 42 may include a second insertion member 421. The second installation member 351 may be inserted into the second insertion member 421. The second electromagnetic shielding member 42 may be coupled to the second side plate 35 by inserting the second installation member 351 into the second insertion member 421. The second insertion member 421 may include a second fixing member 4211 and a second moving member 4212.

The second fixing member 4211 may be in contact with one surface 351a of the second installation member 351. One surface 351a of the second installation member 351 may be a surface opposite to the other surface 351b of the second installation member 351. The other surface 351b of the second installation member 351 may be a surface facing the second front plate 20b positioned adjacent to the second side plate 35.

The second moving member 4212 may be in contact with the other surface 351b of the second installation member 351. That is, the second installation member 351 may be inserted between the second moving member 4212 and the second fixing member 4211. The second fixing member 4212 is configured to move the second mounting member 351 in a direction closer to the second fixing member 4211 after being inserted into the second insertion member 421. It may be elastically connected to 4211. That is, the second moving member 4212 may be connected to the second fixing member 4211 to have an elastic force in a direction closer to the second fixing member 4211. Accordingly, the second moving member 4212 exerts a force on the other surface 351b of the second installation member 351 by the elastic force, so that the second electromagnetic shielding member 42 is formed by the second installation member ( 351 may be firmly coupled.

1 and 9, the second mounting member 351 has the other surface 351b of the second mounting member 351 to increase in size in the direction in which the second mounting member 351 is inserted into the second insertion member 421. This can be formed to be inclined. Therefore, in the process in which the substrate 10 is mounted on the sub-rack body 3 or the substrate 10 is separated from the sub-rack body 3, the sub-rack 1 according to the present invention is the second rack. The electromagnetic shielding member 42 can be prevented from being easily separated from the second installation member 351. The second electromagnetic shielding member 42 is extended from the second mounting member 351 only when an external force that can open the second insertion member 421 is applied to the maximum size of the second mounting member 351. Because it can be separated. In addition, the sub-rack 1 according to the present invention can be prevented from being separated from the second mounting member 351 by the external force generated by the earthquake or the like.

1 and 9, a second locking groove 3511 may be formed on the other surface 351b of the second installation member 351. The second moving member 4212 may include a first locking protrusion 4212a to be inserted into the second locking groove 3511. When the second electromagnetic shielding member 42 is coupled to the second installation member 351, the first catching protrusion 4212a is inserted into the second catching groove 3511. Since the first locking projection 4212a is inserted into the second locking groove 3511, the second electromagnetic shielding member 42 may be prevented from being easily separated from the second installation member 351 by the locking. have.

1 and 9, the second electromagnetic shielding member 42 may include a second shielding member 422. The second shielding member 422 is supported by the second front plate 20b positioned adjacent to the second side plate 35, so that the second side plate 35 and the second front plate 20b are supported. The gap between the liver can be shielded. The second shielding member 422 may be elastically connected to the second fixing member 4211 so as to be supported by the second front plate 20b. That is, the second shielding member 422 may be connected to the second fixing member 4211 so as to have an elastic force in a direction away from the other surface 351b of the second installation member 351. Accordingly, the second shielding member 422 may apply a force to the second front plate 20b by an elastic force. Therefore, the second electromagnetic shielding member 42 can more completely block the electromagnetic wave from moving through the gap between the second side plate 35 and the second front plate 20b.

Although not shown, a plurality of second electromagnetic shielding members 42 may be coupled to the second installation member 351. The second electromagnetic shielding members 42 may be coupled to the second mounting member 351 adjacent to each other in a vertical direction (Y arrow direction) in which the second mounting member 351 protrudes. The second electromagnetic shielding member 42 may be formed such that a plurality of second electromagnetic shielding members 42 are connected in a length direction (Y arrow direction) of the second installation member 351. Accordingly, the number of operations for coupling the second electromagnetic shielding members 42 to the second installation member 351 can be reduced. The second electromagnetic shielding member 42 may be formed so that a plurality of second electromagnetic shielding members 42 are connected to each other with a length corresponding to the length of the second installation member 351. Accordingly, the second electromagnetic shielding members 42 may be coupled to the second installation member 351 in one operation.

1 and 10, the subrack 1 according to the present invention may further include a cover member 5. An electromagnetic shielding material 51 for shielding electromagnetic waves may be formed on one surface 5a of the cover member 5 facing the mounting space 3a. The electromagnetic shielding material 51 may be formed of a material having low contact resistance and excellent shielding effect against electromagnetic waves. For example, the electromagnetic shielding material 51 may be formed of phosphor bronze, beryllium copper, or the like.

The cover member 5 is rotatably formed on the front surface of the sub-rack body 3. The cover member 5 is the electromagnetic shielding material 51 is in contact with the front plate (20, 20 ', 20 ", shown in Figure 1), or the electromagnetic shielding material 51 is the front plate (20, 20 ', 20 "). As the electromagnetic shielding material 51 comes into contact with the front plates 20, 20 ', and 20 ", the electromagnetic shielding material 51 is formed with the front plates 20, 20', 20" and the cover member. 5) It can block the entry of electromagnetic waves through the gap between them. Accordingly, the subrack 1 according to the present invention can protect the substrate 10 mounted inside the sub rack body 3 and other electronic communication devices located outside the sub rack body 3 from electromagnetic waves. The electromagnetic shielding material 51 may be in contact with the top of the front plate (20, 20 ', 20 "). The electromagnetic shielding material 51 is the front panel (20, 20', 20") of the sub-rack It may be formed long in the direction (X arrow direction) located adjacent to the main body (3). When the front plates 20, 20 ', 20 "are separated from the sub-rack body 3, the cover member 5 is pushed by the front plates 20, 20', 20" so that the electromagnetic shielding material 51 may be rotated to be spaced apart from the front plates 20, 20 ', and 20 ". Thus, the substrate 10 is disturbed by the cover member 5 and the electromagnetic shielding material 51. Without this, it can be easily separated from the subrack body 3.

One end of the cover member 5 may be rotatably coupled to the first side plate 34, and the other end thereof may be rotatably coupled to the second side plate 35. The cover member 5 may be rotatably coupled to the first side plate 34 and the second side plate 35 by a shaft 5b, and may be rotated using the shaft 5b as a rotation axis. Can be.

1 to 4, the subrack 1 according to the present invention may further include a connection member 6. The connecting member 6 is installed in the sub rack body 3. The connecting member 6 is electrically connected to the substrate 10 inserted into the guide part 2. The connection member 6 may be connected to the substrate 10 to discharge the excess current to the ground part (not shown) when an excessive current flows in the substrate 10 due to vibration generated by an earthquake or the like. . The substrate 10 may be grounded by the connection member 6 and the ground portion (not shown). Therefore, the subrack 1 according to the present invention can prevent the substrate 10 from being damaged due to vibration generated by an earthquake or the like.

1, 3, and 11, the connection member 6 may include a lower connection member 61 electrically connected to the substrate 10 inserted into the lower guide part 21. . The lower connection member 61 may be coupled to the lower guide part 21. Accordingly, the substrate 10 may be electrically connected to the lower connection member 61 by inserting the substrate 10 into the lower guide part 21. The lower connection member 61 may include a lower connection groove 611 (shown in FIG. 3) for fixing a lower portion of the substrate 10. The lower portion of the substrate 10 may be inserted into the lower connection groove 611. The lower connection groove 611 may be formed to have a width substantially equal to the lower width T1 of the substrate 10. Accordingly, the substrate 10 may be fixed to the lower connection member 61 by being inserted into the lower connection groove 611. Therefore, the subrack 1 according to the present invention can be secured by fixing the substrate 10 so as not to be shaken by an external force generated by an earthquake.

1, 4, and 12, the connection member 6 may include an upper connection member 62 electrically connected to the substrate 10 inserted into the upper guide part 22. . The upper connection member 62 may be coupled to the upper guide part 22. Accordingly, the substrate 10 may be electrically connected to the upper connection member 62 by inserting the substrate 10 into the upper guide part 22. The upper connection member 62 may include an upper connection groove 621 (shown in FIG. 4) for fixing an upper portion of the substrate 10. An upper portion of the substrate 10 may be inserted into the upper connection groove 621. The upper connection groove 621 may be formed to have a width substantially equal to the upper width T3 of the substrate 10 (shown in FIG. 4). Accordingly, the substrate 10 may be inserted into the upper connection groove 621 to be fixed by the upper connection member 62. Therefore, the subrack 1 according to the present invention can be secured by fixing the substrate 10 so as not to be shaken by an external force generated by an earthquake.

1, 3, and 11, the sub rack 1 according to the present invention may further include a lower ground member 71. The sub rack body 3 may be provided with a plurality of lower connection members 61 and 61 ′. The lower connecting members 61 and 61 'may be installed in the sub rack body 3 in a number corresponding to the number of the lower guide parts 21a and 21b. The lower ground member 71 may be electrically connected to the lower connection members 61 and 61 ′, thereby grounding the lower connection members 61 and 61 ′. The lower ground member 71 may be installed on the bottom plate 31. The lower ground member 71 may be connected to the ground portion (not shown). The lower ground member 71 is formed long in the direction (X arrow direction) in which the substrate 10 is located adjacent to the sub-rack body 3 so as to be connected to the lower connection members 61 and 61 '. Can be.

1, 4, and 12, the sub rack 1 according to the present invention may further include an upper grounding member 72. The subrack body 3 may be provided with a plurality of upper connection members 62 and 62 '. The upper connecting members 62 and 62 'may be installed in the sub rack body 3 in a number corresponding to the number of the upper guide parts 22a and 22b. The upper ground member 72 may be electrically connected to the upper connection members 62 and 62 'to ground the upper connection members 62 and 62'. The upper ground member 72 may be installed on the top plate 32. The upper ground member 72 may be connected to the ground portion (not shown). The upper ground member 72 is formed long in the direction (X arrow direction) in which the substrate 10 is located adjacent to the sub rack body 3 so as to be connected to the upper connection members 62 and 62 '. Can be.

Referring to FIG. 13, in order to improve the ease of work in which the substrate 10 is mounted on the subrack 1 according to the present invention, the subrack body 3 may include a fixing groove 36. . A protrusion member (not shown) formed in the front plate 20 may be inserted into the fixing groove 36. The protruding member is formed to protrude in a direction toward the sub rack body 3 when the front plate 20 is coupled to the sub rack body 3. When the front plate 20 is coupled to the sub rack body 3, the protruding member is inserted into the fixing groove 36. The fixing groove 36 may be formed in a shape and size corresponding to the protruding member. Accordingly, the sub rack 1 according to the present invention can prevent the substrate 10 from being easily separated from the sub rack body 3 by an external force generated by an earthquake or the like. Therefore, the subrack 1 according to the present invention can be improved in the anti-vibration, it can be applied to safety-critical equipment such as nuclear power plants.

The fixing groove 36 may be formed in a shape that is reduced in size in the direction in which the protruding member is inserted. The protruding member may be formed to have a size that decreases in the direction in which the protruding member is inserted into the fixing groove 36 to correspond to the fixing groove 36. Accordingly, when the protruding member is inserted into the fixing groove 36, the protruding member is inserted into the fixing groove 36 through an entrance formed with a relatively large size in the fixing groove 36. In addition, the protruding member may be guided so that the substrate 10 is mounted at the correct position in the sub-rack body 3 while being inserted into the fixing groove 36. Therefore, the substrate 10 can be easily mounted on the subrack 1 according to the present invention, and the substrate 10 can be mounted at the correct position.

Referring to FIG. 13, the sub rack body 3 may include a plurality of fixing grooves 36a, 36b, and 36c. The sub rack body 3 may include the fixing grooves 36a, 36b, and 36c in a number approximately equal to the number of the substrates 10. The fixing grooves 36a, 36b, and 36c may be formed in different shapes according to the substrate 10. The fixing grooves 36a, 36b, and 36c may be formed in different shapes according to the function of the substrate 10. For example, as shown in the enlarged view of FIG. 13, the fixing grooves 36a, 36b, and 36c may have a circular cross section, a rectangular cross section, or a pentagonal cross section. It may be formed as. The protruding members formed in the front plates 20, 20 ', and 20 "may be formed in a form corresponding to the fixing grooves 36a, 36b, and 36c, respectively. Thus, the sub-rack 1 according to the present invention ) Can only be inserted into the protruding member having a shape corresponding to the fixing grooves (36a, 36b, 36c), it is possible to ensure that the substrate 10 is mounted in the correct position according to the function of the substrate (10) In addition, since the position to which the substrate 10 should be mounted can be identified from the shape of the fixing grooves 36a, 36b, and 36c of the subrack 1 according to the present invention, the substrate 10 may be removed. It is possible to improve the ease of work for mounting on the sub-rack body 3. The fixing grooves (36a, 36b, 36c) are to be formed in at least one of the lower plate 31 or the upper plate (32). The fixing grooves 36a, 36b, and 36c may be positioned adjacent to the subrack body 3 so that the front plates 20, 20 ′, and 20 ″ are adjacent to each other. In that the direction (X direction of the arrow) may be formed spaced apart from each other at a predetermined distance.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be clear to those who have knowledge.

DESCRIPTION OF SYMBOLS 1 Sub rack 2 Guide part 3 Sub rack main body 4 electromagnetic wave shielding member
5 cover member 6 connection member 10 substrate 20 front plate
21: lower guide portion 22: upper guide portion

Claims (29)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete A sub rack body in which a mounting space for mounting a substrate is formed;
A guide part installed in the sub rack body and into which the substrate mounted on the sub rack body is inserted; And
It includes a cover member rotatably formed on the front of the sub-rack body,
The guide part includes an insertion groove for inserting the substrate, and a fixing protrusion formed to protrude toward the insertion groove so that the width of the insertion groove is reduced to fix the substrate inserted into the insertion groove.
The sub-rack, characterized in that the electromagnetic shielding material for shielding the electromagnetic wave is formed on one surface facing the mounting space from the cover member. delete delete delete delete delete A sub rack body in which a mounting space for mounting a substrate is formed;
A guide part installed in the sub rack body and into which the substrate mounted on the sub rack body is inserted;
A connection member installed in the sub-rack body and electrically connected to the substrate inserted into the guide part to ground the substrate inserted into the guide part;
A first electromagnetic shielding member coupled to a first side plate of the sub-rack body to shield electromagnetic waves;
A second electromagnetic shielding member coupled to a second side plate of the sub-rack body to shield electromagnetic waves; And
And a cover member rotatably formed on an upper surface of the front surface of the sub rack body, and formed with an electromagnetic shielding material for shielding electromagnetic waves on one surface facing the mounting space. delete delete delete

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