Building construction hole topography ponding remove deviceTechnical Field
The invention belongs to the field of building construction, and particularly relates to a device for removing accumulated water in a hollow terrain during building construction.
Background
A building has various pothole topography that cause because of the construction usually during the construction, thereby this kind of pothole topography probably causes building site ponding in rainy day or other circumstances influences safety in production to this ponding that needs to building site carries out timely processing.
But the sediment processing apparatus is not installed to current ponding processing apparatus mostly for thereby it wastes to have handled again the water of water installation inside again after the ponding on ground at every turn and handle when the building site needs dust removal effect again use the water source in addition and cause the waste.
Disclosure of Invention
The utility model provides a building construction hollow topography ponding remove device, the device can be when handling surface ponding water carries out the high-efficient processing of collecting of dregs for ponding can directly be used for so that the use of saving the water source in the dust removal effect.
The utility model provides a construction hole low topography ponding remove device, includes device main part, adjusting sleeve, the inside lower extreme fixed mounting of device main part has the water pump, water pump right-hand member fixedly connected with absorbs water the pipe, water pump top fixed mounting has the header tank.
Preferably, the inside movable mounting of header tank has the bull stick, bull stick lower extreme fixedly connected with flight, bull stick upper end fixedly connected with motor.
Preferably, the bottom of the water collecting tank is arranged in a circular arc mode, the inner wall of the water collecting tank is fixedly connected with a backflow plate, the backflow plate is provided with a roller towards one end of the center, and the backflow plate is arranged in a tilted circular arc mode close to one side of the water collecting tank.
Preferably, the lower end of the reflux plate is fixedly connected with three diversion bumps, the diversion bumps are arranged from small to large from the inner wall of the water collecting tank to the center direction and are obliquely and bent towards the inner side of the water collecting tank.
Preferably, the spiral piece is spirally provided with spiral slag guide grooves, the spiral slag guide grooves are provided with slag through holes at intervals, and the slag through holes are arranged in an arc shape with a large top and a small bottom and are integrally inclined.
Preferably, the roller is provided with a water flow groove, and the water flow groove is integrally inclined and gradually enlarged from left to right.
Preferably, the water suction pipe is fixedly provided with a filter screen inside, the filter screen is arranged at an inclined edge angle at two sides, one section of the two sides of the filter screen facing the inner wall of the water suction pipe is arranged in an inwards concave arc shape, and one section facing the center is arranged in a straight line.
Preferably, an extrusion groove is formed in the inner wall, close to the filter screen, of the water suction pipe, and the left side of the extrusion groove is gradually reduced from inside to outside.
Preferably, the slag collecting device is movably mounted in the extrusion groove, a trigger rod is movably mounted on the outer side of the slag collecting device, the trigger rod is of a movable structure connected with a torsion spring of the slag collecting device, and the outer side of the trigger rod is in curved wave arrangement.
Compared with the prior art, the invention has the following beneficial effects:
1. the filter screen is arranged at the edge angle with two inclined sides, so that when the accumulated water enters the water suction pipe and passes through the filter screen, the accumulated water is blocked to be separated in the first step, the water flow drives the dregs to move towards two sides through the inclined plane, then one section of the two sides of the filter screen facing the inner wall of the water suction pipe is arranged in an inwards concave arc shape, the other section facing the center is arranged in a straight line, so that the water flow can more efficiently drive the dregs to enter the dregs collecting devices at two sides, the trigger rod on the slag collecting device is a movable structure connected with a torsional spring, and the outer side of the trigger rod is provided with a curve wave, so that the effect of water flow on the trigger lever can be increased, the slag collecting device can rotate to collect the slag more efficiently, and simultaneously, the trigger rod is matched with the upper left side of the inner wall of the water absorption pipe to form an extrusion groove which is gradually reduced from inside to outside, so that the trigger bar can move inwards to extrude the dregs to extrude the redundant water in the trigger bar out to prevent the excessive water in the collecting box.
2. One side of the reflux plate close to the water collecting tank is an inclined arc and is arranged with an arc at the bottom of the water collecting tank, so that when the spiral plate rotates to drive accumulated water to move downwards, dregs in the accumulated water can rotate circularly in the reflux plate and are deposited in the dreg accumulating groove to be further separated, thereby ensuring that the water at the upper end of the water collecting tank can be directly used by the spraying device, then three flow guide convex blocks which are obliquely and flexibly arranged towards the inner side of the water collecting tank are arranged on the reflux plate from small to large from the inner wall of the water collecting tank to the central direction, so that the dregs can not flow out of the reflux plate by further limitation, and then a roller which is arranged on the reflux plate and is provided with a water flow groove which is integrally inclined and gradually enlarged from left to right is arranged on the reflux plate, thereby make the rotatory direction of flight drive rivers can increase the effort rotatory to it, further carry out the water conservancy diversion to ponding.
3. Be provided with the spiral through the spiral on the spiral shell and lead the dregs groove for can directly make dregs get into through leading the dregs groove and be interrupted the logical dregs hole that sets up on it when the spiral shell drives dregs downward movement, make in the backward flow board of the below that reaches that dregs can be faster, set up and wholly be the slope form for the arc of big-end-up through leading the dregs hole again, thereby can be according to the rotation direction more efficient water conservancy diversion dregs of spiral shell when making and getting into dregs easily, thereby further improvement dregs separation's efficiency.
Drawings
FIG. 1 is an overall front view of the present invention;
FIG. 2 is an internal perspective view of the present invention;
FIG. 3 is an enlarged view taken at A of FIG. 2 according to the present invention;
FIG. 4 is a top view of the header tank of the present invention;
FIG. 5 is a perspective view of the roller of the present invention;
FIG. 6 is a cross-sectional view of a slag hole of the present invention;
FIG. 7 is a top view of the screen of the present invention;
FIG. 8 is an enlarged view of the invention at B in FIG. 7.
In the figure: 1-device main body, 2-adjusting sleeve, 3-collecting box, 4-spraying device, 5-motor, 6-water collecting tank, 601-slag deposit groove, 7-water pump, 8-rotating rod, 9-filter screen, 10-spiral slice, 1001-spiral slag guide groove, 11-reflux plate, 1101-flow guide projection, 1102-slag guide groove, 12-slag through hole, 13-roller, 1301-water flow groove, 14-water suction pipe, 1401-extrusion groove, 15-slag collecting device and 1501-trigger rod.
Detailed Description
Referring to fig. 1 to 8, a schematic plan structure and a schematic perspective structure of a device for removing accumulated water from a hollow terrain in building construction are shown.
The utility model provides a construction hole low topography ponding remove device, includes devicemain part 1, adjustingsleeve 2, and 1 inside lower extreme fixed mounting of device main part has water pump 7, and water pump 7 right-hand member fixedly connected with absorbswater pipe 14, andwater tank 6 is fixed mounting above water pump 7.
In concrete implementation, 6 inside movable mounting of header tank havebull stick 8, 8 lower extreme fixedly connected with flights ofbull stick 10, 8 upper end fixedly connected withmotors 5 of bull stick for the motor can drive the rotatory dregs to separate in the ponding offlight 10.
In specific implementation, 6 bottoms of header tank are the circular arc setting, 6 inner wall fixedly connected withbackward flow board 11 of header tank, backwardflow board 11 hasgyro wheel 13 towards one of center to serve movable mounting, and backwardflow board 11 leans on one side toheader tank 6 to set up for the slope circular arc, thereby it can make dregs wherein circulate inbackward flow board 11 throughslag guiding groove 1102 and deposit and separate insediment groove 601 whenflight 10 rotation drive ponding moves down and guarantee that the clean ability ofheader tank 3 upper end water is directly used byatomizer 4.
In specific implementation, the lower end of thereflux plate 11 is fixedly connected with adiversion bump 1101, thediversion bumps 1101 are arranged from small to large from the inner wall of thewater collection tank 6 to the center, and are obliquely and curved towards the inner side of thewater collection tank 6, so that dregs are further limited in thereflux plate 11 and cannot flow out, and the dreg separation efficiency is improved.
In concrete implementation, the spiral is provided with spiralguide slag groove 1001 onflight 10, and the interval is provided withlogical sediment hole 12 on spiralguide slag groove 1001, leads to the arc setting thatsediment hole 12 is big-end-up and wholly be the slope form for thereby can follow the rotation direction according toflight 10 more efficient water conservancy diversion dregs in the time of getting into dregs easily, thereby further improvement dregs separation's efficiency.
In concrete implementation, seted uprivers groove 1301 ongyro wheel 13,rivers groove 1301 is whole to be the circular arc setting of slope form and grow gradually from left to right for therebyflight 10 drives the rotatory direction ability increase of rivers and rotates its effort, and further ponding carries out the water conservancy diversion.
In concrete implementation, the inside fixed mounting ofpipe 14 that absorbs water hasfilter screen 9,filter screen 9 is the edges and corners setting of both sides slope, and one section offilter screen 9 bothsides orientation 14 inner walls that absorb water sets up for the indent arc, and one section towards the center is the sharp setting, makes can be blockked when ponding enteringpipe 14 that absorbs water throughfilter screen 9 and go on first step's separation and make rivers drive dregs to remove to both sides through the inclined plane, can make rivers drive during dregs get into thereceipts sediment device 15 of both sides more efficiently simultaneously.
In specific implementation, asqueezing groove 1401 is formed in the inner wall, close to thefilter screen 9, of thewater suction pipe 14, and the left side of thesqueezing groove 1401 is arranged to be gradually reduced from inside to outside, so that thetrigger rod 1501 can move inwards to squeeze dregs after collecting the dregs, and redundant water in the trigger rod is squeezed out to prevent the water in thecollection box 3 from being too much.
In specific implementation, theslag collecting device 15 is movably mounted in theextrusion groove 1401, thetrigger rod 1501 is movably mounted on the outer side of theslag collecting device 15, thetrigger rod 1501 is a movable structure connected with a torsion spring of theslag collecting device 15, and the outer side of the trigger rod is in a curve wave arrangement, so that the action of water flow on thetrigger rod 1501 can be increased, and the slag collectingdevice 15 rotates to collect slag more efficiently.
The working principle of the accumulated water removing device for the hollow terrain in building construction is as follows.
Firstly, push the device main body to the place that needs to handle ponding, make the inside of casingpipe adjusting collar 2 subtend ponding, later start water pump 7 and absorb ponding through thepipe 14 that absorbs water, it is the angular setting of both sides slope to lead tofilter screen 9 in thepipe 14 that absorbs water, make ponding get into can be blockked down when thepipe 14 that absorbs water passes throughfilter screen 9 and carry out the separation of first step and make rivers drive dregs to both sides through the inclined plane and move, one section towards thepipe 14 inner wall that absorbs water throughfilter screen 9 both sides is the setting of indent arc, one section towards the center is the setting of straight line, make rivers can drive dregs more high-efficiently and get into in thereceipts sediment device 15 of both sides, there is the setting of curve wave for torsional spring coupling's movable structure and outside through receiving on thesediment device 15, make the effect that can increase rivers to triggerbar 1501 makereceipts sediment device 15 rotatory carry out more efficient dregs collection, and simultaneously, thetrigger rod 1501 can be matched with the left side on the inner wall of thewater suction pipe 14 to be anextrusion groove 1401 gradually reduced from inside to outside, so that thetrigger rod 1501 can move inwards to extrude dregs after collecting the dregs to extrude redundant water in the dregs to prevent excessive water in the collectingtank 3 from being extruded, when the accumulated water reaches the channelwater collecting tank 6 and needs to be subjected to dust removal operation, the startingmotor 5 drives thespiral sheet 10 to rotate through the rotatingrod 8 to enable the accumulated water to drive the dregs in thespiral sheet 10 to move downwards, one side of thereflux plate 11 close to thewater collecting tank 6 is an inclined arc arrangement and an arc arrangement at the bottom of thewater collecting tank 6, when thespiral sheet 10 rotates to drive the accumulated water to move downwards, the dregs in thereflux plate 11 can rotate in a circulating way and can be deposited in thedreg accumulating groove 601 to further separate, so that the cleanness of the water at the upper end of thewater collecting tank 6 can be ensured to be directly used by thespraying device 4, and three inclined bends from small to large in the direction from the inner wall of thewater collecting tank 6 to the center The guidinglug 1101 arranged in a curve enables dregs to be further limited to be incapable of flowing out in thebackflow plate 11, theroller 13 which is integrally inclined and gradually enlarged from left to right is arranged on thebackflow plate 11 to form thewater flow groove 1301, thespiral sheet 10 drives the direction of water flow rotation to increase the acting force on thespiral sheet 10 so as to rotate, accumulated water is further guided, the spiraldreg guiding groove 1001 is spirally arranged on thespiral sheet 10, when thespiral sheet 10 drives the dregs to move downwards, the dregs can directly enter the dreg throughholes 12 which are discontinuously arranged on the spiraldreg guiding groove 1001, the dregs can quickly reach thebackflow plate 11 below, the dregs can be further guided into thebackflow plate 11 through the dreg through the arc-shaped dreg throughholes 12 which are large at the top and small at the bottom, the dregs can be integrally inclined, and the dregs can be easily fed in, and more efficiently guided to the dregs can be guided according to the rotating direction of thespiral sheet 10, thereby further improving the efficiency of dross separation.