JP2015017388A - Load dispersion structure of equipment storage rack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a load dispersion structure which disperses a load of an equipment storage rack installed on a double floor.SOLUTION: A load, which is applied to a load dispersing steel material 60, is applied to a floor panel 31 through steel material locking nuts 71 and load dispersing bolts 70 by hanging the load dispersing steel material 60 below the floor panel 31 of an upper floor of a double floor using the load dispersing bolts 70 and steel material locking nuts 71, and a load of an equipment storage rack is applied to the load dispersing steel material 60 by nuts 82 for a steel material holding and supporting leg, each screwed to a supporting leg 11 of the equipment storage rack, whereby the load of the equipment storage rack installed on a double floor is dispersed.

Description

  The present invention relates to a load distribution structure that distributes the load of an equipment storage rack installed on a double floor.

  In office floors, server rooms, and data centers of office buildings in recent years, for the wiring of computers and telephone lines used in offices, and for server equipment installed in server rooms and data centers In some cases, the floor surface is a double floor. As a double floor structure, a plurality of support legs are installed on the existing floor surface, and a plurality of floor panels are laid on the support legs, so that there is a gap between the conventional floor surface and the floor panel. There is known a structure in which the film is formed (for example, Patent Document 1).

  When installing a heavy equipment storage rack such as a server rack on the floor surface of such a double floor structure, make sure that the floor surface cannot withstand the load and does not sink or sink. Therefore, there is a demand for a structure that disperses the load applied to the floor and a structure that can withstand the load of a floor panel beyond a certain level. For example, as shown in FIG. 1, as a structure for distributing the load applied to the floor surface, flat steel is installed between the server rack to be installed and the floor panel on the upper surface of the double floor. In many cases, the installation method is such that it is dispersed throughout the steel.

  In addition, as a structure that can withstand a load of a certain level or more, a method of installing a gantry having a structure capable of supporting a load applied to the floor panel under the floor panel is known (for example, Patent Document 2). ).

JP 2003-328543 A JP 2010-270470 A

  If a conventionally known method is used, it is possible to prevent the floor surface from sinking or sinking even when a heavy equipment storage rack is installed on the double floor. However, for example, even if a load-resistant structure is provided at the lower part of the floor panel by the method shown in Patent Document 2, the load is applied from the load-resistant structure to the lower bottom floor of the floor panel. Even if the top floor can withstand the load, the bottom floor of the double floor may not be able to withstand the load.

  In addition, as shown in FIG. 1, when a flat steel is installed between the equipment storage rack to be installed and the floor panel on the upper surface of the double floor to distribute the load, the load applied to one floor panel is reduced. Although it is possible to disperse, the floor panel cannot be opened because it is obstructed by the flat steel, so that there is a problem that it becomes impossible to perform maintenance of the wiring in the gap in the double floor . Furthermore, unevenness is generated on the floor surface due to the thickness of the flat steel, so that the flat steel may obstruct the passage of traffic or may obstruct the installation of equipment such as desks and shelves used in other offices. In addition, when flat steel is installed on uneven floors, the flat steel is not placed in parallel on the floor unevenness, the flat steel installation state is not stable, and sufficient load distribution is achieved. May not be obtained.

  The present invention has been made in view of the problems as described above, and distributes the load of the equipment storage rack installed on the double floor without impairing the convenience of the existing double floor. An object of the present invention is to provide a load distribution structure for an equipment storage rack that prevents the floor surface of the floor from sinking or sinking.

  In order to solve the above problems, the load distribution structure of the equipment storage rack according to the present invention is locked by a load distribution bolt inserted through the floor panel and a steel material locking nut screwed into the load distribution bolt. The load distribution steel material suspended under the top floor panel of the double floor, the support legs of the equipment storage frame through which the floor panel and the load distribution steel material are inserted, and screwed into the support legs This is characterized by comprising an upper nut for a steel material holding support leg that applies the load of the equipment storage rack to the load distribution steel material.

  By adopting such a structure, the load of the equipment storage rack is not directly applied to the floor surface but can be applied to the load distributing steel material. And it can be made the structure where the load applied to the steel material for load distribution is distributed and applied to a plurality of floor panels through the load distribution bolt. In addition, the load distribution steel is suspended in the space under the double floor, and the support legs of the equipment storage rack are fixed to the load distribution steel with the upper nuts for holding the steel material. There is no unevenness on the floor panel of the heavy floor.

  The load distribution bolt may be fixed to the floor panel by sandwiching the floor panel between a head of the bolt and a floor clamping nut screwed to the bolt. .

  By adopting such a structure, the floor panel and the load distribution bolt are firmly fixed and integrated, so that the load applied to the load distribution bolt can be more reliably supported by the floor panel.

  Further, the steel material for load distribution may be fixed to the bolt by being clamped by the nut for locking the steel material and a nut for clamping the steel material screwed to the bolt for load distribution. Good.

  By adopting such a structure, the load distribution steel and the load distribution bolt are firmly fixed and integrated so that the load applied to the load distribution steel can be more reliably applied to the load distribution bolt. It becomes. Furthermore, it is possible to adjust the distance from the floor panel to the load distribution steel so that it is fixed and kept constant, so that the load distribution steel can be prevented from bending and the load can be evenly distributed to the load distribution bolts. become.

  Further, the support leg of the equipment rack is configured such that the floor panel is sandwiched between the upper nut for the floor-holding support leg and the lower nut for the floor-holding support leg that are screwed to the support leg. You may make it clamp the said steel material for load distribution with the upper nut for steel material clamping support legs and the lower nut for steel material clamping support legs.

  By adopting such a structure, the floor panel and the load distribution steel material and the support legs are firmly fixed and integrated, so that the load of the equipment storage rack can be more reliably applied to the load distribution steel material. Become. Furthermore, it is possible to adjust the distance from the floor panel to the load distribution steel so that the distance is fixed and kept constant, so that the load of the equipment storage rack is applied to the load distribution steel with a good balance.

  Moreover, you may make it the said steel material for load dispersion | distribution be either H-section steel, equilateral mountain-shaped steel, I-shaped steel, groove-shaped steel, or flat steel.

  By adopting such a structure, it is possible to uniformly disperse the load applied to the load distribution steel material, and further to prevent the load distribution steel material from being bent.

  According to the present invention, it is possible to install a heavy equipment storage rack on the double floor by distributing the load of the equipment storage rack installed on the double floor to the plurality of floor panels. Become. Furthermore, since unevenness is not generated on the floor surface and opening / closing of some floor panels is not hindered, there is an effect that the convenience of the double floor is not impaired.

It is a perspective view showing the state of the conventional server rack installation. It is a perspective view showing the state of server rack installation. It is a sectional side view showing the state of server rack installation. It is a top view showing the state of server rack installation. It is front sectional drawing showing the state of server rack installation.

  Below, the load distribution structure of the apparatus storage rack which this application discloses is demonstrated in detail based on drawing. In this embodiment, the case where the server rack is installed on the double floor surface will be described. However, the present invention is not limited to the server rack, and there are various weights installed on the office floor, the server room, and the data center. It can be similarly applied to various equipment storage racks.

  In the present embodiment, a load distribution structure when a server rack is installed on a double floor as a device storage rack will be described. FIG. 2 is a perspective view of the server rack installed on the double floor in the present embodiment. Double floor here means installing multiple columns on the base floor, adding multiple floor panels on the columns, and installing a new floor on the original floor. This is a structure where a space is provided between a base floor and a new floor so that wiring and piping can be performed. Double floors are sometimes called free access floors.

  For example, a method of constructing a double floor structure will be described with reference to FIG. 2. First, a plurality of support columns 50 are placed on the lower surface floor 40 in the form of a regular grid at the same height on the lower surface floor 40 as a conventional foundation. Install securely. Then, a plurality of substantially square floor panels 31 are laid out so that four points near the apex are supported by different pillars 50. Thus, the upper surface floor 30 is formed by supporting the floor panel 31 with the support columns 50. A double floor structure is thus formed.

  Next, consider a case where the server rack 10 is installed on the upper floor 30 of the double floor configured as described above. For example, it is assumed that the weight of the server rack 10 is 300 kg and the loading capacity of the server rack 10 is 600 kg. The load resistance per sheet of the floor panel 31 is assumed to be 150 kg. In such a case, when the server rack 10 is installed so as to be supported by the four floor panels 31, when only the main body of the server rack 10 is first installed on the top floor 30, the weight of the server rack 10 is Since the weight is 300 kg, the weight applied to the floor panel 31 is 75 kg per sheet, which is less than the load resistance per sheet of the floor panel 31, so that the server rack 10 can be installed on the upper floor 30 without any particular problem. .

  However, when server devices, uninterruptible power supply devices, storage devices, etc. are stored in the server rack 10 and the total weight of the storage device reaches 600 kg, which is the maximum load capacity of the server rack 10, the server rack 10 The total weight is 900 kg, and the weight on one floor panel 31 is 225 kg. If so, the load capacity per one floor panel 31 is significantly exceeded, and the upper floor 30 may not be able to withstand the load of the server rack 10 and may sink or sink. Furthermore, when the load capacity of a predetermined region of the lower floor surface 40 is exceeded, there is a risk that even the lower floor surface 40 may sink or sink.

  In such a case, it is necessary to disperse the load of 900 kg of the total weight of the server rack 10 and to apply the weight applied to the floor panel 31 per sheet so that the load resistance per sheet of the floor panel 31 is 150 kg or less. In this embodiment, the load distribution structure in such a case will be described.

  FIG. 3 is a side sectional view when the server rack 10 is installed on a double floor by applying the load distribution structure of the equipment storage rack in the present invention, and FIG. 4 is a top view. In the load distribution structure in the present invention, the load distribution steel material 60 is suspended under the floor panel 31 of the upper floor of the double floor by using the load distribution bolt 70 and the steel material locking nut 71, thereby distributing the load. The load applied to the steel material 60 is applied to the floor panel 31 through the heads of the steel material locking nut 71 and the load distribution bolt 70.

  For example, when the server rack 10 is supported by the support legs 11 provided at the four corners of the lower surface of the server rack 10, as shown in FIG. 4, the server rack 10 passes under the two support legs 11 that are in a straight line. Thus, the substantially rectangular load dispersing steel 60 is suspended. Therefore, in order to pass all the column legs 11 at the lower four corners of the server rack 10, the two load distribution steel members 60 are suspended. When the number of support legs 11 is different from that of the present embodiment, it is possible to suspend a plurality of load distribution steel materials 60 so as to pass under the support legs 11 according to the number of support legs 11. is there.

  Next, a method for suspending the load dispersing steel 60 will be described in detail. An insertion hole for allowing the load distribution bolt 70 to be inserted through the floor panel 31 and the load distribution steel material 60 is provided. Although one floor panel 31 preferably has one insertion hole, when a plurality of load distribution steel members 60 are installed in accordance with the arrangement of the support legs 11, a plurality of floor panels 31 have a plurality of holes. The insertion hole may be provided.

  A plurality of insertion holes of the load distribution steel material 60 are provided so as to overlap with the insertion holes provided in the floor panel 31, and the load distribution bolts 70 are inserted into the insertion holes of the floor panel 31 so that the head faces the upper surface. The shaft portion is inserted so as to penetrate the insertion hole of the load distribution steel material 60. Then, a steel material locking nut 71 is screwed onto the shaft portion of the load distribution bolt 70 that has passed through the insertion hole of the load distribution steel material 60.

  As described above, the load distribution bolt 70 is inserted into each of the plurality of insertion holes provided in the floor panel 31 and the load distribution steel material 60, and the steel material locking nut 71 is screwed into the bolt, thereby distributing the load. The steel material 60 is locked by a plurality of steel material locking nuts 71, and the floor panel 31 and the load distribution steel material 60 are connected by the load distribution bolts 70 and the steel material locking nuts 71.

  In this case, the weight of the load distribution steel material 60 applied to the steel material locking nut 71 is supported by the floor panel 31 through the head of the load distribution bolt 70, and the load distribution steel material 60 is a double floor. It will be in the state suspended under the upper surface floor 30.

  By installing the load distribution steel 60 so as to be suspended from the plurality of floor panels 31 in this way, the load applied to the load distribution steel 60 is distributed to the plurality of floor panels 31 connected by the load distribution bolts 70. Then it starts to hang. In this case, the load can be evenly distributed by screwing the steel material locking nut 71 to the load distribution bolt 70 so that the distance from the floor panel to the load distribution steel material 60 is uniform.

  Next, a structure for supporting the load of the server rack 10 with the load distribution steel 60 suspended under the upper floor 30 of the double floor will be described. FIG. 5 is a front sectional view showing a state in which the support legs 11 of the server rack 10 are connected to the load distribution steel material 60. The floor panel 31 and the load distribution steel material 60 are provided with insertion holes through which the support legs 11 are inserted.

  First, the support legs 11 of the server rack 10 are inserted into the insertion holes of the floor panel 31. And the support leg 11 is inserted in the insertion hole of the steel material 60 for load distribution so that the upper nut 82 for the steel material clamping support leg screwed together may become the upper surface side of the steel material 60 for load distribution. By doing so, the load of the server rack applied to the support leg 11 is applied to the load distribution steel material 60 through the upper member 82 for holding the steel material support legs.

  In this way, each support leg 11 of the server rack 10 is connected to the load distribution steel 60 to the load distribution steel 60. As a result, the load of the server rack 10 is applied to the load distribution steel material 60, and the load applied to the load distribution steel material 60 is distributed to the plurality of floor panels 31 through the load distribution bolts 70 and the steel material locking nuts 71. It comes to hang.

  For example, when there are four support legs 11 of the server rack 10 and the total weight is 900 kg, when the server rack 10 is simply installed on the upper surface floor 30, the load applied to the floor panel 31 is about one piece. 225 kg. On the other hand, the case where the load distribution structure in the present embodiment is used will be considered. For example, as shown in FIG. 4, five load distribution bolts 70 and steel material locking nuts 71 are connected to two load distribution steel members 60, respectively, and are suspended from five floor panels 31 each. The support legs 11 of the server rack 10 are connected to the two load distribution steel members 60 at two locations, and the load of the server rack 10 is applied to the load distribution steel members 60 through the upper nuts 82 for holding the steel material support legs. Install the unit so that it is hung. As a result, the load of the server rack 10 is distributed and applied to the 10 floor panels 31, and the load applied to the floor panel 31 is 90 kg per sheet. Thereby, for example, even when the load resistance per sheet of the floor panel 31 is only 150 kg, the load of the server rack 10 having a total weight of 900 kg can be distributed and supported.

  Further, as shown in the conventional installation method of FIG. 1, it is not necessary to install the flat steel 20 between the equipment storage rack to be installed and the upper surface of the double floor. Floor panels other than the ones in which the support legs 11 of the rack 10 are inserted can be freely opened and closed, and the occurrence of unevenness of the floor surface when the flat steel 20 is installed can be prevented. Furthermore, since the load applied to the support 50 is also distributed, even if the load resistance in a predetermined region of the lower floor surface 40 cannot withstand the weight of the server rack 10, the load applied to the lower floor surface 40 is distributed. The

  Furthermore, as an effective load distribution structure, a floor panel clamping nut 73 is screwed onto the lower surface side of the floor panel 31 of the shaft portion of the load distribution bolt 70 that penetrates the floor panel 31, so that the load distribution bolt 70 It is also possible to adopt a structure in which the floor panel 31 is clamped by the head and the floor panel clamping nut 73 so as to be joined. As a result, the load applied to the load distribution steel 60 can be more reliably supported by the floor panel 31.

  Further, a steel material clamping nut 72 and a steel material clamping nut 72 are screwed into the upper surface side of the load distribution steel material 60 of the shaft portion of the load distribution bolt 70 penetrating the load distribution steel material 60. Thus, it is possible to adopt a structure in which the load dispersing steel 60 is sandwiched and fixed so as to be joined. As a result, the distance between the floor panel 31 and the load distribution steel material 60 can be adjusted to be constant, and the load applied to the load distribution steel material 60 can be transmitted to the floor panel 31 efficiently and in a balanced manner. It becomes like this.

  Further, the floor panel 31 is clamped and fixed by the floor clamping support leg upper nut 80 and the floor clamping support leg lower nut 83 screwed into the support leg 11 of the server rack 10 penetrating the floor panel 31. The steel member 60 for load distribution is sandwiched between the upper nut 82 for holding the steel material support leg and the lower nut 81 for holding the steel material holding support leg screwed into the support leg 11 of the server rack 10 that penetrates the load distribution steel material 60. It is also possible to adopt a structure in which the support legs 11, the floor panel 31, and the load distribution steel material 60 are fixed. By doing so, it becomes possible to adjust the distance between the floor panel 31 and the load distribution steel 60 to be constant, and the load of the server rack 10 can be transmitted to the load distribution steel 60 efficiently and in a balanced manner. become able to.

  In the present embodiment, the structure in the case where the support legs 11 of the server rack 10 are directly joined to the load distribution steel material 60 has been described. However, the equipment support bolts are inserted from the upper surface of the floor panel 31, and the support legs are inserted. 11 can be substituted. In this case, the support leg 11 of the server rack 10 is installed so as to be placed on the upper surface of the equipment support bolt, so that the load of the server rack 10 is applied to the equipment support bolt. The same effect as the load distribution structure can be obtained.

  3 and 4, the load distribution steel 60 is a substantially rectangular flat steel. However, the load distribution steel 60 may be H-shaped steel, equilateral mountain-shaped steel, I-shaped steel, or groove. By using the shape steel, the load distribution steel 60 is prevented from bending due to the shape characteristics of the steel, and the load applied to the load distribution steel 60 is more reliably transmitted to the floor panel 31 through the load distribution bolt 70. Will be able to.

  The embodiments of the present invention have been described above with reference to the drawings. However, the technical scope of the present invention is not affected by the above-described embodiments, and those skilled in the art will understand the technical scope described in the claims. Of course, modifications that are apparently conceived within the scope of the idea belong to the technical scope of the present invention.

10 server rack 11 support leg 20 flat steel 30 upper floor 31 floor panel 40 lower floor 50 support 60 load distribution steel 70 load distribution bolt 71 steel material locking nut 72 steel material clamping nut 73 floor surface clamping nut 80 floor clamping support Upper nut for leg 81 Lower nut for holding support leg of steel material 82 Upper nut for holding support leg of steel material 83 Lower nut for support leg of floor holding

Claims (5)

A load distribution structure of an equipment storage rack that distributes the load of the equipment storage rack installed on the upper floor panel of the double floor to a plurality of floor panels, and a load distribution bolt (70) inserted through the floor panel; The steel for load distribution (60) suspended below the upper floor panel of the double floor by being locked by a steel material locking nut (71) screwed to the load distribution bolt (70) And a support leg (11) of the equipment storage rack through which the floor panel and the load distribution steel (60) are inserted, and the load of the equipment storage rack is screwed into the support leg (11). A load distribution structure of an equipment storage rack characterized by comprising a steel material holding support leg upper nut (82) applied to a dispersion steel material (60). The load distribution bolt (70) is clamped to the floor panel by clamping the floor panel with a head of the bolt and a floor clamping nut (73) screwed to the bolt. The load distribution structure of the equipment storage rack according to claim 1. The load distribution steel material (60) is clamped between the steel material locking nut (71) and the steel material clamping nut (72) screwed into the load distribution bolt (70), whereby the bolt The load distribution structure of the equipment storage rack according to claim 1, wherein the load distribution structure is fixed to the equipment storage frame. The support leg (11) supports the floor panel with a steel material sandwiched by a floor clamping support leg upper nut (80) and a floor clamping support leg lower nut (83) screwed to the support leg (11). The load of the equipment storage rack according to any one of claims 1 to 3, wherein the load distribution steel material (60) is clamped by a leg upper nut (82) and a steel material clamping support leg lower nut (81). Distributed structure. 5. The equipment storage according to claim 1, wherein the load distribution steel is one of H-shaped steel, equilateral mountain-shaped steel, I-shaped steel, groove-shaped steel, and flat steel. Load distribution structure of the rack.