Summary of the invention
The object of this invention is to provide a kind of assembled athletic floor, this athletic floor is not only assembled efficient and convenient, after wherein a few floor is subject to expanding with heat and contract with cold and produces deformation, can not have an impact to being attached thereto the floor connect, and elasticity feet provide better flexible install simultaneously also firmly convenient.
The technical scheme that the present invention solves the employing of its technical problem is: a kind of assembled athletic floor, which comprises at least: rigid structural layer and the resiliency supported layer be fixed on bottom rigid structural layer, it is characterized in that: rigid structural layer sidepiece two corresponding sides are respectively the draw-in groove end and buckle end that match, and wherein draw-in groove end or buckle end are elastic constructions.
Described rigid structural layer is rectangular configuration, and two adjacent edges of Rectangular Rigid deck sidepiece are draw-in groove end, and other two adjacent edges of sidepiece are buckle end.
Described draw-in groove end is several m shape elasticity draw-in grooves stretching out spaced apart, m shape elasticity draw-in groove only two bases is fixedly connected with Rectangular Rigid deck sidepiece is vertical, have clamping ring in the middle of m shape elasticity draw-in groove, buckle end is then mate the clamping projection connected and fixed with this clamping ring.
Described buckle end comprises grab, clamping projection, rectangular preiection composition, and wherein two grabs and the projection of the clamping between it form a clamping unit, are rectangular preiections between adjacent two clamping unit.
Described rigid structural layer is rectangular configuration, and the sidepiece of Rectangular Rigid deck wherein one group of corresponding sides is respectively the draw-in groove end and buckle end that match, and another group corresponding sides are the through grooves with radian.
Two described rigid structural layer have through groove ends and mutually dock, and two rigid structural layer connected by U-shaped bar after docking, U-shaped bar is elastic strip, and U-shaped bar crooked radian wherein mates with the radian of through groove.
Described draw-in groove end is several rectangular card channel openings spaced apart, and it is protruding that buckle end is that spaced apart several have the buckle being bent upwards radian, and buckle projection is elastomeric material.
Described draw-in groove opening inner side is fixed with the limited block corresponding with buckle convex curved radian, and a draw-in groove opening inner side distributes multiple limited block.
Distance between described adjacent two buckle projections is greater than in the distance 2mm between adjacent two draw-in groove openings.
Be the rigid support system of interlaced arrangement anyhow bottom described rigid structural layer, each crosspoint of support system forms each leg of rigid structural layer, and leg place is fixed with elasticity feet, and each elasticity feet forms resiliency supported layer jointly.
The invention has the beneficial effects as follows: because sidepiece two adjacent edge in rigid structural layer adds elasticity draw-in groove, other two adjacent edges of sidepiece are buckle end, therefore be elasticity connection between the assembled rear each floor of this athletic floor, after wherein a few floor is subject to expanding with heat and contract with cold and produces deformation, the elastic construction of junction can absorb the displacement of this athletic floor, ensure that its displacement can not have an impact to being attached thereto the athletic floor connect; The resiliency supported layer at rigid structural layer bottom supports place installs accurate positioning and convenience simultaneously, the stressed height exceeding leg 2-5mm makes it can be supported by leg when receiving and compressing more completely, makes the elasticity of this athletic floor meet relevant criterion completely; The rigid structural layer upper epidermis that dislocation is arranged can shelter from the seam of two athletic floor junctions.
Accompanying drawing explanation
Below in conjunction with embodiment accompanying drawing, the present invention is further described.
Fig. 1 is the structural representation of the embodiment of the present invention 1;
Fig. 2 is the structural representation of buckle projection in the embodiment of the present invention 2;
Fig. 3 is the structural representation of draw-in groove opening in the embodiment of the present invention 2;
Fig. 4 is the structural representation of limited block in the embodiment of the present invention 2;
Fig. 5 is the structural representation of the embodiment of the present invention 2;
Fig. 6 is support system structural representation;
Fig. 7 is feet structural representation;
In figure: 1, rigid structural layer; 2, resiliency supported layer; 3, elasticity draw-in groove; 4, clamping ring; 5, grab; 6, clamping is protruding; 7, rectangular preiection; 8, support system; 9, leg; 10, feet; 11, feet holder; 12, positioning convex; 13, detent; 14, upper epidermis; 15, bayonet socket; 16, through groove; 17, U-shaped bar; 18, draw-in groove opening; 19, buckle is protruding; 20, limited block.
Detailed description of the invention
This assembled athletic floor is the resiliency supported layer 2 comprising rigid structural layer 1 and be fixed on bottom rigid structural layer 1, and rigid structural layer 1 sidepiece two corresponding sides are respectively the draw-in groove end and buckle end that match, and wherein draw-in groove end or buckle end are elastic constructions.
The buckle end of wherein floorboard is connected in draw-in groove end, because wherein one end is elastic construction, therefore be elasticity connection between the assembled rear each floor of this athletic floor, wherein floorboard to be expanded with heat and contract with cold etc. after reason produces deformation, its displacement acts on the elasticity draw-in groove of junction, the elastic shrinkage of elasticity draw-in groove or stretching, extension can dissolve the displacement of this athletic floor, ensure that this displacement can not have an impact to being attached thereto the athletic floor connect, ensure that the steadiness of this athletic floor entirety.
Embodiment 1
As shown in this athletic floor example structure schematic diagram of Fig. 1, its rigid structural layer 1 is rectangular configuration, two adjacent edges of Rectangular Rigid deck 1 sidepiece are draw-in groove end, and other two adjacent edges of sidepiece are buckle end, and the regular-shape motion floor splicing being convenient to polylith same size forms monoblock athletic ground.
Wherein the buckling groove end of two adjacent edges is all several m shape elasticity draw-in grooves 3 stretching out spaced apart, m shape elasticity draw-in groove 3 is fixedly connected with Rectangular Rigid deck sidepiece is vertical by means of only the bottom on two limits, left and right, the centre of m shape elasticity draw-in groove 3 is then clamping ring 4, corresponding buckle end then has the clamping projection 6 of mating with this clamping ring 4, after two athletic floor splicings, clamping projection 6 extends in clamping ring 4, it can be passed to another block athletic floor by clamping projection 6 after the athletic floor of buckle end is stressed, but the special construction due to m shape makes middle card T-Ring 4 can have certain elastic space, the deformation that the athletic floor of buckle end is produced or displacement can not be passed to the elasticity draw-in groove end motion floor being attached thereto and connecing.
The buckle end corresponding with m shape elasticity draw-in groove 3 comprises grab 5, clamping projection 6, rectangular preiection 7, wherein two grabs 5 and the clamping between it protruding 6 form a clamping unit, rectangular preiection 7 between adjacent two clamping unit, each clamping unit is all corresponding to be connected with one of them m shape elasticity draw-in groove 3, wherein clamping projection 6 extends in clamping ring 4, rigid structural layer sidewall locations corresponding to the space place between clamping ring 4 with limit, two, left and right has bayonet socket 15, grab 5 is connected in bayonet socket 15, for the ease of installing, grab 5 only afterbody and Rectangular Rigid deck is fixed, thus make grab 5 have certain fore-aft travel space, during clamping, grab 5 first inwardly shrinks, restoring to the original state after running into bayonet socket 15, it is fixing to realize, it is the space between the adjacent two m shape elasticity draw-in grooves 3 of rectangular preiection 7 correspondences between adjacent two clamping unit, overall steadiness is added after connection.
Clamping ring 4 is cylindric or horse-hof shape, corresponding clamping projection 6 is similarly cylindric or horse-hof shape, the external diameter of clamping projection 6 is less than the internal diameter of clamping ring 4, the rigid structural layer sidewall locations of clamping ring 4 correspondence is jagged, if the athletic floor be attached thereto transmits larger displacement by clamping protruding 6, clamping ring 4 to breach direction elastic shrinkage, can absorb this displacement.
Embodiment 2
In the structure of the present embodiment, rigid structural layer 1 is rectangular configuration, the sidepiece of Rectangular Rigid deck 1 wherein one group of corresponding sides is respectively the draw-in groove end and buckle end that match, and another group corresponding sides are the through grooves 16 with radian, the sidepiece of the through whole rigid structural layer 1 of through groove 16.
As shown in Figure 5, when corresponding sides have two athletic floor splicings of through groove 16, through groove 16 end of two rigid structural layer 1 docks mutually, by U-shaped bar 17, two rigid structural layer are connected after docking, U-shaped bar 16 wherein crooked radian on one side mates with the radian of through groove 16, therefore to dock the run-though space of rear formation consistent with the U-shaped structure of U-shaped bar 17 for two through grooves 16, and U-shaped bar is elastic strip, connects into as a whole by having flexible U-shaped bar 16 by two athletic floors.
Other two corresponding sides of rigid structural layer 1 are the draw-in groove end and buckle end that match respectively, draw-in groove end is several rectangular card channel openings 18 spaced apart, see Fig. 3, buckle end is that spaced apart several have the buckle projection 19 being bent upwards radian, see Fig. 2, buckle projection 19 is elastomeric materials.
Be fixed with multiple limited block 20 that to distribute inside corresponding limited block 20, the draw-in groove opening 18 of 19 crooked radians protruding with buckle inside draw-in groove opening 18 simultaneously, see Fig. 4.
Only need the wherein buckle projection 19 of a piece be connected in the draw-in groove opening 18 of another block when two rigid structural layer 1 are interconnected, the arcuate structure of buckle projection 19 matches with the arc-shaped limit block 20 in draw-in groove opening 18, carry out spacing, after this mode is assembled, two interconnective athletic floor fore-and-aft directions are forced through band radian buckle protruding 19 and control, left and right directions is stressed then to be controlled by the lattice gear between draw-in groove opening 18, the buckle projection 19 of elastomeric material can dissolve the mutual displacement of athletic floor, ensure that this displacement can not have an impact to being attached thereto the athletic floor connect.
Distance between adjacent two buckle projections 19 is greater than the distance between adjacent two draw-in groove openings 18, and the distance be greater than is in 2mm, can guarantee that buckle projection 19 is connected in draw-in groove opening 18 smoothly like this when not affecting global reliability.
Embodiment 3
As shown in the support system structural representation of Fig. 6, it is the rigid support system 8 of interlaced arrangement anyhow bottom rigid structural layer 1, each crosspoint of support system 8 forms each leg 9 of rigid structural layer, and leg 9 place is fixed with elasticity feet 10, and each elasticity feet 10 forms resiliency supported layer 2 jointly.
Diagonal positions in each " # " font support unit of the formation of interlaced arrangement anyhow of support system 8 is all fixed with hard material, each support unit is reinforced, from but the intensity of whole support system 8 obtains reinforcement further, the rigid support system 8 of rigid structural layer and hard material are all identical with support column material in the elastic sports floor of earlier application.
There is the feet holder 11 of hollow structure at leg 9 place of spaced distribution in support system 8, in the present embodiment, feet holder 11 is cylindrical, the flexible feet positioning convex 12 in inner upper end center of cylindrical feet holder 11, feet 10 is fixed in feet holder 11, and guarantee that feet 10 accurately can be fixed on the center in feet holder 11 by positioning convex 12, and do not offset after fixing.
By arranging feet holder 11 at leg 9 place of spaced distribution, and feet 10 being fixed on this structure of formation resiliency supported layer 2 in feet holder 11, making each strong point distribution of resiliency supported layer 2 more even, stressed rear support better effects if.
Feet 10 structure as shown in Figure 7, feet 10 is cylindrical elastomeric, elastic body can be rubber or other there is flexible material, the top center of cylindric feet 10 has detent 13, detent 13 matches with the positioning convex 12 in feet holder 11, and the external diameter of feet 10 is less than the hollow structure internal diameter of feet holder 11.
The height of feet 10 is that in feet holder, hollow structure height adds 2-5mm.The present embodiment is that in feet holder, hollow structure height adds 3mm, so just can guarantee that feet 10 is fixed on after in feet holder and can extend 3mm, after rigid structural layer 1 is stressed, make overall structure have the elastic buffer space of 3mm, the elasticity of this athletic floor guaranteed, if more than the elastic buffer height of 3mm, when feet 10 is compressed in feet holder completely, can be supported by leg 9 equally, make the elasticity of this athletic floor meet relevant criterion completely.
Embodiment 4
The upper surface of rigid structural layer 1 has upper epidermis 14, upper epidermis is dislocation layout, namely upper epidermis to rigid structural layer 1 body one of them or adjacent two directions skew 1-2cm, see Fig. 1, the upper surface of upper epidermis 14 has face coat, and the concrete material composition of face coat is identical with face coat component in earlier application.
Upper epidermis 14 in the present embodiment is the upper right side skew 1cm to rigid structural layer 1 body, this just makes the upper epidermis 14 of rigid structural layer upper surface right and top respectively extend 1cm, and within the scope of the 1cm of left and below, there is no upper epidermis 14, the dislocation constituting upper epidermis is arranged, the lower left that the upper epidermis offset above the assembled rear right of polylith athletic floor just covers another block athletic floor does not have the position of upper epidermis 14.
Dislocation arranges that the upper epidermis 14 of rigid structural layer 1 can shelter from the seam of two athletic floor junctions, makes the gap depth of seam crossing be only the thickness of upper epidermis 14, is convenient to cleaning.