CN210421806U - Antistatic epoxy terrace of high strength - Google Patents

Abstract

The utility model discloses a high-strength antistatic epoxy terrace, which comprises a terrace substrate, wherein an epoxy sealing substrate, an antistatic mortar layer and an epoxy putty layer are respectively formed on the surface of the terrace substrate from bottom to top, and antistatic epoxy finish paint is formed on the surface of the epoxy putty layer; still include a plurality of parallel arrangement's electrically conductive sectional shelf-unit simultaneously, electrically conductive sectional shelf-unit is including the area body and the conductor metal pole of shaping on the area body to contact ground the wire at one end connection, the area body is made for rigidity conducting material, and the shaping has a plurality of concave-convex surfaces of equidistant on it, concave-convex surface's evagination summit position fixed connection the conductor metal pole, conductor metal pole upper surface shaping is in epoxy putty layer, and the lower surface top leans on the terrace base member surface. The utility model relates to a rationally, structural stability is good, intensity is high, and can effectively prevent that terrace surface static from gathering.

Description

Antistatic epoxy terrace of high strength

Technical Field

The utility model relates to a reform transform epoxy terrace structure among the terrace technical field, specifically be an antistatic epoxy terrace of high strength.

Background

The terrace structure is a common ground structure which is directly improved for the ground of the bottom soil bottom surface or the simple cement prefabricated bottom surface and the like, generally requires certain strength, rigidity and wear resistance, and also has certain specific requirements for moisture resistance, water resistance and wear resistance.

At present, terrace structure on the market usually uses epoxy terrace paint and polyurethane terrace paint as the main, and in order to satisfy above-mentioned demand, terrace structure can set up to multilayer composite construction usually and realizes the reinforcement of certain specific function or obtaining certain function, for example in some hospitals, accurate electron factory workshop, pharmaceutical factory workshop, computer lab, electric control room, laboratory, weaving factory etc. need prevent static place, ordinary terrace is because often receive the friction and gather a large amount of static charges easily, the accumulation of these static is easy to be influenced to some precision equipment or electronic equipment's normal use and pile up material storage, still can cause the conflagration when serious, accidents such as explosion, therefore need lay antistatic terrace. However, the common antistatic terrace on the market is usually too simple in structure, not only has a general antistatic effect, but also has low impact strength, and is not suitable for being used as an area which needs to be moved frequently for placing articles in workshops, warehouses and the like and has certain requirements on antistatic performance.

SUMMERY OF THE UTILITY MODEL

The utility model provides an antistatic epoxy terrace of high strength to solve the shortcoming in the above-mentioned background art.

The utility model provides a technical problem adopt following technical scheme to realize:

a high-strength antistatic epoxy terrace comprises a terrace substrate, wherein an epoxy sealing substrate, an antistatic mortar layer and an epoxy putty layer are respectively formed on the surface of the terrace substrate from bottom to top, and antistatic epoxy finish paint is formed on the surface of the epoxy putty layer; still include a plurality of parallel arrangement's electrically conductive sectional shelf-unit, electrically conductive sectional shelf-unit contacts to earth the wire in one end connection, electrically conductive sectional shelf-unit is including the area body and the shaping conductor metal pole on the area body, the area body is made for rigidity conducting material, and the shaping has a plurality of concave-convex surfaces of equidistant on it, the evagination summit position fixed connection of concave-convex surface the conductor metal pole, conductor metal pole upper surface shaping is in epoxy putty layer, and the lower surface pushes up and leans on the terrace base member surface.

By way of further limitation, the floor substrate is preferably cementaceous.

As a further limitation, the belt body is formed by forging and pressing a copper or copper-aluminum alloy belt.

By way of further limitation, the concave-convex surface formed on the belt body is one of an arc-shaped concave-convex surface, a trapezoidal concave-convex surface and a square wave-shaped concave-convex surface.

As a further limitation, the thickness of the belt body in the conductive combined bracket is 1.5-3 mm, the width of the belt body is 20-50 mm, and the distance between every two adjacent conductive combined brackets is 50-80 mm.

As a further limitation, the lower part of the conductor metal rod is provided with a base which is fixedly connected with the floor matrix through the base, and the fixedly connected mode is adhesive adhesion.

As a further limitation, the conductor metal rod is a metal screw rod, which is fixed on the position of the outward convex vertex of the belt body in a threaded connection mode and is adhered to the surface of the floor substrate at the position of the nut through an adhesive.

As a further limitation, the adjacent conductor metal rods are connected at the lower parts through copper wires and form a grid-shaped conductive copper mesh so as to improve the conduction efficiency and the overall stability of the conductive combined bracket.

As a further improvement, the antistatic epoxy finish paint is preferably a water-based antistatic epoxy self-leveling finish paint.

As a further improvement, the antistatic epoxy finish paint can be replaced by a soluble polyether-ether-ketone modified epoxy resin paint so as to further improve the mechanical strength, corrosion resistance and oxidation resistance of the epoxy floor surface.

Has the advantages that: the utility model forms a space-distributed conductive grid by implanting the conductive combined bracket and the conductor metal rod in the floor material layer for reinforcement, and can lead free charges carried on the surface-free floor into the ground for neutralization by matching with the grounding wire; simultaneously this kind of space grid structure can also form effective support and buffering in the terrace material layer to effectively improve the stability and the impact resistance on terrace material layer after the shaping, therefore, be used for storage space, garage etc. need often take place the regional practicality that terrace surface strikes than traditional epoxy terrace stronger.

Drawings

Fig. 1 is a schematic diagram of a preferred embodiment of the present invention.

Wherein: 1. a floor substrate; 2. an epoxy-enclosed substrate; 3. an antistatic mortar layer; 4. a belt body; 5. a copper wire; 6. a conductor metal rod; 7. an epoxy putty layer; 8. antistatic epoxy finish.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand and understand, the present invention is further explained by combining with the specific drawings.

Referring to fig. 1, in the present embodiment, the epoxy floor is formed on a cement ground and the cement ground is used as a floor substrate 1, and a conductive composite support is disposed on the surface of the floor substrate 1, the conductive composite support is a parallel strip-shaped structure and includes a strip body 4 and a conductive metal rod 6 formed on the strip body 4, and a grounding wire is further connected to an outer side of the conductive composite support to release and neutralize accumulated static charges.

In the embodiment, the belt bodies 4 are formed by forging and pressing metal copper belts, the thickness of a single belt is 2mm, the width of the single belt is 40mm, and the distance between adjacent belt bodies 4 is 60 mm. Whole area body 4 all takes shape in antistatic mortar layer 3 in order to conveniently carry out stable in structure, its arc concave-convex surface that has equidistant setting, and the bottom outer fringe interval between the adjacent arc arch is 22mm in these arc concave-convex, and the central point interval between the adjacent arc arch is 120 mm.

In the embodiment, the position of the center point of the bulge of the belt body 4 is provided with the internal thread, and the metal screw is screwed at the position of the internal thread to be used as the conductor metal rod 6, so that the selected conductor metal rod 6 has good consistency, and the purchase is convenient to reduce the cost. And the metal screw rods as the conductor metal rods 6 are connected at the lower parts through copper wires 5 to form a latticed conductive copper mesh so as to improve the conduction efficiency and the overall stability of the conductive combined bracket. During construction, conductor metal pole 6 is at the nut position earlier through the adhesive bonding in order to conveniently stand it on the surface of terrace base member 1 and carry out follow-up construction, after the adhesion, can form epoxy sealing substrate 2 in proper order at terrace base member 1, antistatic mortar layer 3 and epoxy putty layer 7, wherein, the surface shaping is in epoxy putty layer 7 on conductor metal pole 6, the lower surface then through the adhesive adhesion and lean on terrace base member 1 on the surface, and treat that epoxy putty layer 7 shaping is stable after, then can come to carry out the surface course through coating waterborne antistatic epoxy self-leveling finish paint as antistatic epoxy finish paint 8 and seal on its surface.

In another embodiment, the conductive metal rod 6 is a common copper rod with a base, the belt body 4 is provided with a hole corresponding to the arc-shaped protruding position, the upper part of the copper rod of the conductive metal rod 6 passes through the hole and is fixed with the belt body 4 in a welding mode, and the lower surface of the base can be adhered and fixed with the floor base 1 through glue application.

In another embodiment, the antistatic epoxy finish paint 8 is a soluble polyether-ether-ketone modified epoxy resin paint, and the use of the paint can further improve the mechanical strength, corrosion resistance and oxidation resistance of the epoxy floor surface.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A high-strength antistatic epoxy terrace comprises a terrace substrate and is characterized in that an epoxy sealing substrate, an antistatic mortar layer and an epoxy putty layer are respectively formed on the surface of the terrace substrate from bottom to top, and antistatic epoxy finish paint is formed on the surface of the epoxy putty layer; still include a plurality of parallel arrangement's electrically conductive sectional shelf-unit, electrically conductive sectional shelf-unit contacts to earth the wire in one end connection, electrically conductive sectional shelf-unit is including the area body and the shaping conductor metal pole on the area body, the area body is made for rigidity conducting material, and the shaping has a plurality of concave-convex surfaces of equidistant on it, the evagination summit position fixed connection of concave-convex surface the conductor metal pole, conductor metal pole upper surface shaping is in epoxy putty layer, and the lower surface pushes up and leans on the terrace base member surface.

2. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the floor substrate is a cementitous ground.

3. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the belt body is formed by forging and pressing a copper or copper aluminum alloy belt.

4. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the concave-convex surface formed on the belt body is one of an arc concave-convex surface, a trapezoid concave-convex surface and a square wave concave-convex surface.

5. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the thickness of the belt body in the conductive combined support is 1.5-3 mm, the width is 20-50 mm, and the distance between adjacent conductive combined supports is 50-80 mm.

6. The high-strength antistatic epoxy floor as claimed in claim 1, wherein a base is disposed under the conductive metal rod and is fixedly connected to the floor substrate through the base.

7. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the conductive metal rod is a metal screw fixed to the position of the outward convex vertex of the belt body in a threaded manner and fixedly connected to the floor base at the position of the nut.

8. The high-strength antistatic epoxy floor as claimed in any one of claims 6 or 7, wherein the conductor metal rod is fixedly connected to the floor substrate by adhesive bonding.

9. The high-strength antistatic epoxy floor as claimed in claim 1, wherein the adjacent conductive metal rods are connected at the lower part by copper wires, and the connected copper wires form a grid-shaped conductive copper mesh on the lower plane of the conductive metal rods.

10. The high-strength antistatic epoxy floor level according to claim 1, wherein the antistatic epoxy finish is a water-based antistatic epoxy self-leveling finish.

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