NL1017802C2 - Metallic network increased floor structure. - Google Patents

Description

Metallic network increased floor structure.

The present invention relates to a metallic network raised floor part structure with lightweight. The floor part structure has an increased capacity to bear concentrated loads. The floor part is applicable in various areas such as factories, family homes, school classrooms, office buildings, computer centers or meeting rooms.

More and more information products have been used extensively in various fields, including computers, fax machines, copiers, modems, printers, telephones, and so on. These information products are connected by wires for supplying power or sending signals. For example, U.S. Patent No. 5,628,157 shows a metallic raised floor portion with wire channels for receiving different types of wires and for decorating the environment. Such a raised floor section can easily be covered and maintained.

The above-mentioned raised floor part is filled with concrete for increasing the capacity to bear concentrated loads. Such a measure can strengthen the compressive strength of the floor part. However, the total weight of the building will increase. This can influence the back pressure, anti-earth shock and load-bearing capacity of a building, in particular with regard to old buildings.

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Therefore, it is necessary to provide a metallic network raised floor part structure with a light weight and increased capacity to withstand load. The raised floor part is made of a flat iron panel and a concave iron plate which are firmly attached to each other without filling with concrete.

To this end, it is a primary object of the present invention to provide a metallic network raised floor part structure with a light weight. The floor part structure has an increased capacity for bearing loads.

It is a further object of the present invention to provide the aforementioned metallic network raised floor part structure which can be manufactured faster and can be used immediately after manufacture.

It is a still further object of the present invention to provide the aforementioned metallic network raised floor part structure which shortens work time at the construction site and saves costs.

It is a still further object of the present invention to provide the aforementioned metallic network raised floor part structure that can be easily maintained and can guarantee safety.

According to the above-mentioned objects, the metallic network raised floor part structure of the present invention is made of a metallic raised floor part, leg elements, base seats, wire channels, central cover plates and side cover plates. The metallic raised floor part is made of a flat iron panel with a plurality of punch openings at equal distances and a concave iron plate with a plurality of concave parts which are connected to the flat iron panel. Four corners of the raised floor part are formed with holes in which the plastic collar of the rubber element is placed. The edge of the raised floor part 3 is formed with a flange with recesses in which the side cover plate is placed. The plastic collar is securely fitted with a metal nut into which a threaded rod with a fixing nut is screwed. Four sides of the base seat are formed with recesses in which teeth of wire channels are placed. Four corners of the base seat are provided with upwardly protruding hollow cylindrical hubs in which the threaded rod of the raised floor section leg member is placed. The raised floor members are interconnected to define cross grooves in which the wire channel seat, central cover plates, side cover plates are locked and a wire outlet seat is arranged. The wire channel is a U-shaped frame body. The front and rear ends thereof are respectively formed with two teeth corresponding to the recesses of the base seat. The central cover plate is a square plate body. Each of its four corners is formed with a wire opening. Two sides of each wire opening are formed with assisting positioning plates. The side cover plate is a rectangular plate body. Two lateral sides thereof are formed with downwardly curved arcuate positioning plates and downwardly projecting assisting positioning plates. The wire outlet seat can have a size that is equal to that of the side cover plate for quick installation.

The present invention can best be understood by the following description and accompanying figures, wherein: Figure 1 is a cut-away perspective view of the present invention; Figure 2 is a sectional view in the assembled state of the present invention; Figure 3 is a sectional view showing that the raised floor part and leg element of the present invention are constructed by means of a tool; Figure 3A is a perspective view which

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4 shows the assembled raised floor part and leg element of the present invention for compacting; Figure 4 is a sectional view showing that the positioning plate of the side cover plate 5 is coupled into the recess of the flange of the raised floor portion of the present invention; Figure 5 is a sectional view showing the height adjustment of the raised floor portion of the present invention; and Figure 6 shows the application of the raised floor part of the present invention.

Reference is made to Figures 1 and 2. The metallic raised floor part structure of the present invention is made of a raised floor part 1, leg elements 2, base seats 3, wire channels 4, central cover plates 5 and side cover plates 6. The raised floor part 1 is formed of a square iron flat panel 11 with punch openings 12 at equal distances. Each punch opening 12 has downwardly extending opening walls 121. A concave iron plate 16 with a plurality of concave parts is provided in the opening wall 121. Then, the opening wall 121 is punched to securely connect the concave iron plate 16 to the iron panel 11. The edge of the raised floor part 1 is formed in steps to form a flange 13 with recesses 14 at intervals.

Moreover, the four corners of the raised floor part 1 are formed with hexagonal holes 15.

The leg element 2 comprises a plastic collar 21 which corresponds to the hexagonal hole 15 and is provided therein. The underside of the plastic collar 21 is formed with a flange 22. A metal nut 23 with an internal thread 26 is further arranged in the plastic collar 21. The outer circumference of the metal nut 23 is formed with a flange 25 and longitudinally machined stripes 24 for increasing the rigidity of the fit with the plastic collar 21 and to prevent rotation. The metal nut 23 is screwed with a threaded rod 27 which is provided

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St v 5 of a fastening nut 28 and a C-shaped ring 281. The upper end of the threaded rod 27 is incised with a slot 29 for a blade screwdriver in the upper end to adjust the height of the threaded rod 27. The leg element 2 is assembled immediately after the raised floor part 1 has been manufactured in the factory. Therefore, it is not necessary to fix the leg element on the construction site.

The basic seat 3 is a square body. Each of its four sides is formed with a recess 31. Each of the four corners is provided with an upwardly projecting hollow cylindrical hub 32 for mounting with the threaded rod 27 of the leg member 2.

The wire channel 4 is a U-shaped frame body. Front and rear sides thereof are respectively formed with two teeth 41 which correspond to the recesses 31 of the basic seat.

The central cover plate 5 is also a square plate body. Each of its four corners is formed with a wire opening 51. Two sides of each wire opening 51 are formed with assisting positioning plates 52.

The side cover plate 6 is a rectangular plate body. Two lateral sides thereof are formed with downwardly curved arcuate positioning plates 61 and downwardly projecting assisting positioning plates 62.

Referring to Figure 3, after the raised floor portion 1 is manufactured in the factory, the raised floor portion 1 is inverted with the hexagonal hole 15 disposed on a projecting spindle 91 of each corner of a tool 9. The plastic collar 21 of the leg element 2 is arranged in and securely positioned in the hexagonal hole 15. Then the end with the machined stripes 24 of the metal nut 23 is provided in the plastic collar 21 to fit securely into the plastic collar 21. Furthermore, the threaded rod 27 on which the fixing nut 28 is screwed is passed through the C-shaped ring 281 and then screwed into the metal nut 23 until the threaded rod 27 abuts the top of the projecting spindle 91 of the tool 9. Accordingly, the 5 leg elements 2 of the raised floor parts 1 released by the factory will have a uniform height X without difference. Such a raised floor part 1 is specifically designed for offices so that it has a certain height X. At the construction site, it is not necessary to assemble the leg-10 elements so that the labor efficiency can be increased. Moreover, referring to Figure 3A, the iron material is relatively heavy. However, the two raised floor parts 1 can overlap each other to form a hollow configuration. This reduces volume and weight of the raised floor parts 1 so that the raised floor parts 1 can easily be packed and moved without increasing shipping costs.

Reference is made to Figures 4 to 6. The teeth 41 of four wire channels 4 are placed in the recesses 31 of four sides of the base seat 3. Then the wire rod 27 of the leg element 2 is connected to each corner of four raised floor parts 1. into the hollow cylindrical hub 32 of the base seat 3. Wires 8 are laid freely in the wire channels 4. A central cover plate 5 is then placed between four raised floor parts 1. The assisting positioning plates 52 next to the thread openings 51 of the central cover plate 5 are slightly recessed so that the four thread openings 51 can easily be laid against the hexagonal holes of the four raised floor parts 1. Now four screws are used to lock the central cover plate 5 on the four raised floor parts 1. In addition, the arcuate positioning plate 61 on one side of each of different side cover plates 6 (or wire outlet seats 7) is coupled into the recess 14 of the flange 13 of the raised floor part 1. (The sharp edge of the positioning plate is concealed to scrape the wires such as II 017 S ..

7 shown in Figure 4). The assisting positioning plate 62, on the other hand, can also be easily coupled to the end section of the flange 13 to complete the assembly of the raised floor part structure.

In the case of an irregular floor surface, as shown in figures 2 and 3, the screws of the central cover plate 5 are unscrewed. The plastic collar 21 is firmly inserted into the hexagonal hole 15 and the metal nut 23 engages the plastic collar 21 by means of the machined stripes 24 so that the raised floor part 1, plastic collar 21 and the metal nut 23 integrally with each other be connected. A blade screwdriver is inserted into the slot 29 of the threaded rod 27 to rotate clockwise or counterclockwise in the threaded rod 27 for adjusting the height thereof. In the case that it is necessary to adjust the threaded rod 27 to a higher position, after being adjusted, the side cover plate 6 is raised to further tighten the fastening nut 28. In the case that the threaded rod 27 needs to be adjusted To a lower position, it is necessary to first raise the side cover plate 6 to loosen the fastening nut 28. After the adjustment is complete, the fastening nut 28 is tightened again.

The metallic network raised floor part structure of the present invention has the following advantages: 1. The flat iron panel and the concave iron plate are directly firmly connected to each other through the punch openings without the use of cement. Therefore, the metallic raised floor part has a light weight and also an increased capacity for bearing loads.

2. The metallic raised floor part is made by direct tight connection

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8 so that after being assembled, the metallic raised floor part can be used immediately. In contrast to the present invention, it takes three weeks for the use of the conventional cement raised floor part. That is why production can be accelerated and costs reduced.

3. The metallic raised floor part has a light weight so that a building is protected from excessive stress and safety can be ensured.

4. The metallic raised floor part has light weight so that it is easy and time-saving to move it or to work on the metallic raised floor part.

The embodiment described above has only been used to illustrate the present invention and is not intended to limit the scope thereof. Many changes can be made to the embodiment described above without departing from the inventive concept of the present invention.

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Claims (11)

1. Metallic network raised floor part structure comprising a raised floor part, leg elements, base seats, wire channels, central cover plates and side cover plates which are assembled together, wherein the raised floor part is a square body of a certain size, an edge of the raised floor part is stepped to form a flange, wherein four corners of the raised floor part are formed with holes into which the leg element fits, which leg element is made of a plastic collar, a metal nut, a fixing nut and a threaded rod, with four sides of the base seat are formed with recesses in which teeth of wire ducts are placed, and the four corners of the base seat are provided with upwardly directed hollow cylindrical hubs in which the raised element of the raised floor part is placed, the raised floor parts being interconnected for cross grooves to define in which the central cover plates and z ice cover plates are enclosed. 2. Metallic network raised floor part structure according to claim 1, wherein the raised floor part is made of a flat iron panel with several punching hole hubs at equal distances and a concave iron plate with several concave parts, each comprising a central continuous opening, the punching hole hub of the flat iron panel is placed in the continuous opening and pressed to securely connect the concave iron plate to the flat iron panel. 3. The metallic network raised floor part structure of claim 1, wherein the holes of the raised floor part are hexagonal. . "-p ^ The metallic network raised floor part structure according to claim 1, wherein the flange of the raised floor part is formed with recesses at equal intervals. The metallic network raised floor part structure of claim 1, wherein the plastic collar of the leg element is a hexagonal collar corresponding to the holes of the raised floor part, wherein a bottom of the plastic collar is formed with a flange. 10 The metallic network raised floor part structure of claim 1, wherein the outer circumference of the metal nut of the leg element is formed with a flange and machined stripes for placement in the plastic collar with the inner circumference of the metal nut formed with an inner thread. The metallic network raised floor part structure of claim 1, wherein a C-shaped ring and a mounting nut are placed on the threaded rod of the leg element. The metallic network raised floor part structure of claim 7, wherein an upper end of the threaded rod is cut with a slot for a hand tool to advance the threaded rod. 9. The metallic network raised floorboard structure of claim 1, wherein each of the four corners of the central cover plate is formed with a wire opening, recessed assisting positioning plates being formed adjacent to each wire opening for positioning on two adjacent sides of a corner of the raised floor part. 10. The metallic network raised floor part structure of claim 1, wherein two lateral sides of the side cover plate are formed with downwardly curved arcuate positioning plates and recessed assisting plates. The metallic network raised floor part structure of claim 10, wherein the positioning plates of the side cover plate are directly coupled in the recesses of the flange of the raised floor part. oooooooo RB / KP 'I' Π ': j ή ft t ·' ·,!>, ') U /