JP7495219B2 - Rail mounting structure - Google Patents

Description

The present invention relates to a rail mounting structure for installing large electronic devices such as servers.

Conventionally, to install large electronic devices such as servers, a floor panel was placed in the space above a concrete slab, and the electronic devices were attached to rails embedded in the floor panel (see non-patent document 1).
This type of structure has the advantages of making installation and replacement work easy by allowing the electronic devices to be moved along the rails, making it possible to change the installation position depending on the dimensions and layout of the electronic devices, and allowing the space below the floor panel to be used as air conditioning space and wiring space.

Senqsia Co., Ltd. "Senqsia Free Access Floor System", published in May 2019, pp. 32-36

However, the structure described in Non-Patent Document 1 requires floor panels and support devices that support the floor panels in a floating state, and the installation of these devices is also necessary, which increases costs. In particular, in recent years, the performance of servers and other devices has improved, making strict air conditioning less necessary than before, and there is an increasing demand to reduce the costs of creating a raised floor.
The problem to be solved by the present invention is to provide a rail mounting structure that can easily mount a rail to an existing slab at low cost.

The invention of claim 1 is a rail mounting structure for fixing a rail onto a slab that is used without a floor material on its upper surface, characterized in that the entire rail is exposed to the outside of the slab, reinforcing plates are fixed onto the slab with gaps between them in the longitudinal direction of the rail , and multiple rails are fixed onto the reinforcing plates in a parallel arrangement with gaps between them.
The invention of claim 2 is a rail mounting structure as described in claim 1, characterized in that the rail has a groove-shaped cross-sectional shape with a bottom plate, metal fittings slide inside, the reinforcing plate and the rail are made of metal, and the rail is fixed to the reinforcing plate by a countersunk screw that penetrates the bottom plate of the rail.
The invention according to claim 3 is the rail mounting structure according to claim 1 or 2, characterized in that the rail is for mounting a server rack and has a cross-sectional shape of a lipped groove.
As another invention, the following may be also provided.
Configuration 1 is a rail mounting structure for fixing a rail onto a slab that is used without a floor material on its upper surface, characterized in that the entire rail is exposed to the outside of the slab, a reinforcing plate is fixed onto the slab, and multiple rails are fixed onto the reinforcing plate in a parallel arrangement with gaps between them.
Configuration 2 is a rail mounting structure described in configuration 1, characterized in that the rail has a groove-shaped cross-sectional shape with a bottom plate, metal fittings slide inside, the reinforcing plate and the rail are made of metal, and the rail is fixed to the reinforcing plate by a countersunk screw that penetrates the bottom plate of the rail.
Configuration 3 is the rail mounting structure according to configuration 1 or 2, characterized in that the rail is for mounting a server rack and has a cross-sectional shape of a lipped groove.
Furthermore, as another invention, the following may be possible.
Means 1 is a rail mounting structure for fixing a rail to a slab, characterized in that the entire rail is exposed to the outside of the slab.

Means 2 is the rail mounting structure according to Means 1 , characterized in that a reinforcing plate is fixed to the slab, and the rail is fixed to the reinforcing plate.

Means 3 is the rail mounting structure described in Means 2 , characterized in that the reinforcing plate and the rail are made of metal, and the rail is fixed to the reinforcing plate by a countersunk screw that penetrates the bottom plate of the rail.

Means 4 is the rail mounting structure according to means 1 , characterized in that the rail is directly fixed to the slab.

Means 5 is the rail mounting structure described in Means 4, characterized in that the rail is fixed to the slab via a hole-in anchor consisting of a sleeve driven into the slab and a very low head bolt penetrating the bottom plate of the rail and screwed into the sleeve .

Means 6 is a rail mounting structure according to any one of means 1 to 5 , characterized in that a plurality of rails are arranged in parallel with a space therebetween.

Means 7 is a rail mounting structure according to any one of means 1 to 6, characterized in that the rail is for mounting a server rack and has a cross-sectional shape of a lipped groove.

According to the present invention, rails can be easily attached to existing slabs and there is no need to install floor panels above the slab, which reduces the number of parts, reduces the labor required for construction, and keeps costs low.

In addition, by fixing a reinforcing plate to the slab and then fixing the rail to the reinforcing plate, the slab can be prevented from being damaged by the weight of the items supported by the rail.

In addition, by fixing the rail to the reinforcing plate with a countersunk screw that penetrates the bottom plate of the rail, the protruding parts that prevent the metal fittings of large electronic devices such as servers from sliding inside the rail can be made small, and by making the reinforcing plate and rail out of metal, the through holes in the rail through which the countersunk screws pass and the screw holes in the reinforcing plate into which the countersunk screws are screwed can be precisely formed in advance at the factory.

In addition, the number of parts can be further reduced by fixing the rails directly to the slab.

In addition, by fixing the rails with hole-in anchors consisting of sleeves driven into the slab and thin, low-head bolts that penetrate the bottom plate of the rail, the protruding parts inside the rails are small, so that metal fittings on large electronic devices such as servers are less likely to get in the way of sliding inside the rails.

In addition, by arranging multiple rails in parallel with a space between them, items such as large electronic devices can be stably supported.

In addition, by making the cross-sectional shape of the rail for mounting the server rack a groove shape with a lip, when the mounting bracket for fixing the server rack is engaged with the inside of the rail, the mounting bracket gets caught on the lip and is less likely to come off, preventing the server rack from falling over.

1 is a cross-sectional view of a rail mounting structure showing a first embodiment of the present invention; FIG. 4 is a cross-sectional view of a rail mounting structure showing a second embodiment of the present invention.

The following describes an embodiment of the present invention with reference to the drawings. It goes without saying that the present invention is not limited to the embodiment.

First Embodiment
A first embodiment of the present invention will now be described with reference to FIG.
FIG. 1 is a cross-sectional view of a rail mounting structure showing a first embodiment.

In the first embodiment, the rail mounting structure is for fixing a rail 1 for mounting a server rack to the upper surface of a concrete slab 2 .
The rail 1 is for mounting a server rack, and is formed by bending a metal plate, and its cross-sectional shape is a groove with a lip.
A metallic reinforcing plate 3 is fixed to the upper surface of the concrete slab 2, and a plurality of rails 1 (two in this embodiment) are fixed to the upper surface of the reinforcing plate 3 in parallel with each other at intervals.

The reinforcing plate 3 may be a long plate having a length along the longitudinal direction of the rail 1, or may be a short plate arranged at appropriate intervals along the longitudinal direction of the rail 1.
Furthermore, the reinforcing plate 3 is fixed to the concrete slab 2 between the two rails 1 and at both ends via hole-in anchors 4. There are no particular limitations on the type of hole-in anchor 4 as long as it has sufficient mounting strength, and the number of hole-in anchors 4 can be increased or decreased depending on the required mounting strength.

Further, a screw hole 5 is formed in the reinforcing plate 3 at the position where the rail is attached, and an insertion hole 6 for inserting a countersunk screw is formed in the bottom plate (web) of the rail 1 at a position corresponding to the screw hole 5. The insertion hole 6 is shaped so that the head of the countersunk screw 7 can fit in it.
Then, the bottom plate of the rail 1 is placed on the upper surface of the reinforcing plate 3, the screw hole 5 and the insertion hole 6 are aligned, and a countersunk screw 7 is passed from above the bottom plate of the rail 1 through the insertion hole 6 and screwed into the screw hole 5, thereby fixing the rail 1 to the concrete slab 2 with the entire rail 1 exposed to the outside of the concrete slab 2.

In this way, the underside of the bottom plate of the rail 1 contacts the upper surface of the reinforcing plate 3, and the other parts are located above the reinforcing plate 3 which is placed above the concrete slab 2, so dust generated on the concrete slab 2 is less likely to accumulate inside the grooved rail 1. Since dust is less likely to accumulate inside the rail 1, the server's mounting brackets can be moved smoothly when the server is moved again.
Furthermore, since the reinforcing plate 3 and the rail 1 are both made of metal, the screw holes 5 and the insertion holes 6 can be formed in advance in a factory with high precision with respect to their positions and dimensions.

To install a server rack on a concrete slab 2, mounting brackets slidably and fixably engaged in the rails 1 are attached to the server rack, the server rack is spanned across the two rails 1, and then the mounting brackets are slid to move the server rack to an installation position, and the mounting brackets are fixed to the rails 1.
Since the top surface of the bottom plate of the rail 1 and the head of the countersunk screw 7 are almost flush with each other, the sliding of the mounting bracket is not impeded and the server rack can be moved smoothly.

When installing a plurality of server racks of different dimensions, a pair of short channel members are stretched across two rails 1, and the channel members and rails 1 are connected by connecting fittings that are slidably and fixedly engaged within the rails 1.
Furthermore, the mounting brackets, which are slidably and fixably engaged within the channel members, are slid in accordance with the dimensions of the server rack placed on the pair of channel members, and the mounting brackets are attached to the server rack and then fixed to the channel members.
Next, the connecting fitting is slid along the rail 1 to slide the channel member to the installation position of the server rack, and then the connecting fitting is fixed to the rail 1.

Second Embodiment
A second embodiment of the present invention will be described below with reference to Fig. 2. Note that a description of the same parts as in the first embodiment will be omitted, and differences will be mainly described.
In a second embodiment, the rail 1 is fixed directly to the concrete slab 2 .

Since it is difficult to form highly accurate screw holes in the concrete slab 2, in this embodiment, the rail 1 is fixed to the concrete slab 2 by a hole-in anchor 4' consisting of a sleeve 11 driven into the concrete slab 2 and an extremely low head bolt 12 inserted into an insertion hole 6 provided in the bottom plate of the rail 1 and screwed into the sleeve 11.
The insertion hole 6 is not shaped to match the head of the countersunk screw 7 as in the first embodiment, but has a shape that allows the neck portion of the extremely low head bolt 12 to be inserted therethrough.

In the second embodiment, the method of using the rail mounting structure is similar to that of the first embodiment.
The head of the extra-low head bolt 12 is very thin and overlaps the bottom plate of the rail 1 via a thin washer 13, so that it does not protrude significantly into the inside of the rail 1 and the metal fitting can slide smoothly inside the rail 1.

In addition, the underside of the bottom plate of the rail 1 is in contact with the top surface of the concrete slab 2, and the other parts are located above the concrete slab 2, so dust generated on the concrete slab 2 is less likely to accumulate inside the groove-shaped rail 1. Since dust is less likely to accumulate inside the rail 1, the server's mounting brackets can be moved smoothly when the server is moved again.

[Other Modifications]
The present invention is not limited to the above-described embodiment, and may also include the following, for example.

In this embodiment, the rails are for mounting a server rack, but they may also be for mounting other items.

In this embodiment, the cross-sectional shape of the rail is a groove with a lip, but the cross-sectional shape can be changed to an H-shape or other shape depending on the structure of the metal fittings that slide inside the rail.

The technical aspects of any of the embodiments may be applied to other embodiments to provide examples. For example, the countersunk screw 7 in the first embodiment may be applied to the second embodiment. In this case, the thin washer 13 is not used in the second embodiment, and the insertion hole 6 is shaped to fit the head of the countersunk screw 7.

REFERENCE SIGNS LIST 1 Rail 2 Concrete slab 3 Reinforcement plate 4, 4' Hole-in anchor 5 Screw hole 6 Insertion hole 7 Countersunk screw 11 Sleeve 12 Extra low head bolt 13 Washer

Claims (3)

A rail mounting structure for fixing a rail onto a slab that is used without a floor material on its upper surface, the entire rail being exposed to the outside of the slab,
A rail mounting structure characterized in that reinforcing plates are fixed onto the slab at intervals in the longitudinal direction of the rail , and a plurality of the rails are fixed onto the reinforcing plates in a parallel arrangement at intervals. The rail has a cross-sectional shape of a groove having a bottom plate, and a metal fitting slides inside the rail,
2. The rail mounting structure according to claim 1, wherein the reinforcing plate and the rail are made of metal, and the rail is fixed to the reinforcing plate by a countersunk screw that penetrates the bottom plate of the rail. The rail mounting structure according to claim 1 or 2, characterized in that the rail is for mounting a server rack and has a cross-sectional shape of a lipped groove.