CN113832973A - Device is administered in mine side slope infiltration of open pit - Google Patents

Abstract

The invention discloses an open mine side slope water seepage treatment device, and relates to the technical field of water seepage treatment, wherein a grouting pipe is arranged on a rack in a sliding manner, the bottom of the peripheral side of the grouting pipe is communicated with a spray head, a driving mechanism is used for driving the grouting pipe to slide on the rack, a rotating pipe is sleeved on the grouting pipe in a sliding manner along the axial direction of the grouting pipe and is connected to the rack in a rotating manner, an inclined elliptical groove is annularly formed in the peripheral side of the rotating pipe, two ends of the long axis of the elliptical groove are respectively communicated with an arc-shaped recess deviating from the long axis of the elliptical groove, the two arc-shaped recesses are symmetrical relative to the center of the elliptical groove, the elliptical groove and the two arc-shaped recesses form a driving groove, a sliding part is connected in the driving groove in a sliding manner, and a driving unit is used for driving the sliding part to reciprocate along the axial direction of the rotating pipe. The invention can adjust the rotating, swinging and fixed spraying of the spray head only by adjusting the stroke of the reciprocating motion of the sliding part, and can adjust the swinging and spraying angle of the spray head in the swinging and spraying process, thereby being very convenient to operate.

Description

Device is administered in mine side slope infiltration of open pit

Technical Field

The invention relates to the technical field of water seepage treatment, in particular to a water seepage treatment device for a side slope of an open mine.

Background

The side slope seepage of the open mine is a phenomenon with higher occurrence probability, and the current effective treatment method aiming at the side slope seepage is a high-pressure injection grouting method, a hole is drilled at a seepage position, a grouting pipe is introduced to the bottom of the drilled hole, slurry is pumped into the grouting pipe through a high-pressure liquid pump to be sprayed out through an alloy nozzle on the grouting pipe, soil body is impacted and damaged, soil particles are mixed with the slurry under the comprehensive actions of the impact force of a jet flow beam, centrifugal force, gravity and the like, and are regularly rearranged according to a certain slurry-soil proportion and mass, after the slurry is solidified, a coagulation body with a certain shape is formed in the soil, and the high-efficiency seepage blocking effect is achieved. The direction and duration of nozzle movement is related to the shape of the condensate formed, and generally nozzles have three spray patterns: the grouting pipe is lifted and continuously rotated, and the nozzle is rotated to form a columnar coagulation body; the grouting pipe is lifted and rotates in a reciprocating manner, and the nozzle is swung and sprayed to form a dumbbell-shaped coagulation body; the grouting pipe is only lifted and does not rotate, the direction of the nozzle is fixed, and the nozzle performs fixed spraying to form a plate-shaped coagulation body. According to the difference of soil layers, a proper spraying mode is selected to form a specific coagulation body shape, so that the effect of plugging and permeating can be improved.

If the publication number is CN111501764B, the publication date is 20210518, and the name is "a large-angle swing-jet high-pressure injection grouting machine", the invention comprises a lifting platform, a drill rod is arranged at the top of the lifting platform in a penetrating manner, the drill rod is rotatably connected with the lifting platform, a drill bit is fixedly connected at the bottom end of the drill rod, a plurality of spray heads are fixedly connected at the bottom end of the side wall of the drill rod, a first gear is fixedly sleeved on the outer wall of the drill rod above the lifting platform, a second gear and a third gear are rotatably connected at the top of the lifting platform, the first gear and the third gear are mutually meshed with each other, a frame is fixedly connected at the top of the lifting platform, a first hydraulic cylinder is connected at the top of the frame in a penetrating manner, a driving column is fixedly connected at the bottom of the first hydraulic cylinder, and a driving hole is arranged at the center of the top of the second gear in a penetrating manner, the inner wall symmetry fixedly connected with two drive blocks of drive hole, the bottom of drive post is located the drive hole, the bottom of lift platform is located the drive hole and runs through under the drive hole and be provided with the through-hole. It can realize fixed spraying; swinging and spraying of the grouting machine are realized through a first hydraulic cylinder, a driving column, a driving groove, a driving block and the like; the rotary spraying of the swing spraying of the grouting machine is realized through a second hydraulic cylinder, a motor, a matching block, a matching groove and the like.

In the prior art, a common grouting machine can only carry out fixed-position injection, or the fixed-position injection is combined with swing injection, or the fixed-position injection is combined with rotary injection; although the above patent can realize fixed spraying, swinging spraying and rotating spraying, the swinging spraying and the rotating spraying are driven by two sets of completely independent driving mechanisms, so that not only is the structure redundant, but also interference exists between the two sets of driving mechanisms, and the operation is inconvenient.

Disclosure of Invention

The invention aims to provide a water seepage treatment device for a side slope of an open mine, which aims to overcome the defects in the prior art.

In order to achieve the above purpose, the invention provides the following technical scheme: a slope seepage treatment device for an open mine, which comprises a frame, a grouting pipe, a driving mechanism, a rotating pipe and a sliding part, wherein the grouting pipe is arranged on the frame in a sliding way, the bottom of the periphery of the grouting pipe is communicated with a spray head, the driving mechanism is arranged on the frame, the rotating pipe is sleeved on the grouting pipe in a sliding manner along the axial direction of the grouting pipe, the rotating pipe is rotationally connected to the frame, an inclined elliptical groove is annularly arranged on the peripheral side of the rotating pipe, two ends of the long axis of the elliptical groove are respectively communicated with an arc-shaped recess deviating from the long axis of the elliptical groove, the two arc-shaped recesses are symmetrical relative to the center of the elliptical groove, the oval groove and the two arc-shaped depressions form a driving groove, the sliding part is connected in the driving groove in a sliding mode, and the driving unit is used for driving the sliding part to reciprocate along the axis direction of the rotating pipe.

Further, fixedly connected with guide bar in the frame, sliding connection has the slider on the guide bar, slip casting pipe rotate connect in on the slider.

Furthermore, the driving mechanism comprises a speed reducing motor, a transmission assembly, a chain, a first chain wheel and a second chain wheel, the speed reducing motor drives the first chain wheel to rotate through the transmission assembly, the second chain wheel is rotatably connected to one end, far away from the rack, of the guide rod, the chain is meshed and sleeved on the first chain wheel and the second chain wheel, and two open ends of the chain are fixedly connected to the sliding piece.

Further, the transmission assembly comprises a shaft rod, a first gear and a second gear, the shaft rod is rotatably connected to the guide rod, the first gear and the first chain wheel are coaxially and fixedly connected to the shaft rod, and the second gear is coaxially and fixedly connected to a rotating shaft of the speed reducing motor.

Furthermore, the driving unit comprises an intermittent gear, two racks, a sliding support, a connecting part and an adjusting component, the intermittent gear is coaxially and fixedly connected to the shaft rod, the sliding support is connected to the guide rod in a sliding mode and fixedly connected with the two racks, the two racks are parallel to the guide rod, the two racks are located on two opposite sides of the circumference of the intermittent gear, the intermittent gear is alternately meshed with the two racks in the rotating process, one end of the connecting part is fixedly connected with the sliding part, the other end of the connecting part is connected with one of the racks in a sliding mode, and the adjusting component is used for adjusting the sliding stroke of the connecting part on the corresponding rack.

Further, the regulating assembly includes dwang and two sliding blocks, the dwang rotates to be connected on sliding support, two the sliding block slides respectively and sets up on the rack that connecting portion corresponded, and two sliding blocks are located the both sides of connecting portion, two be connected with a nut, two on the sliding block respectively coaxial and internal thread revolve to opposite, be provided with two sections external screw threads that revolve to opposite on the dwang to make the dwang respectively with two nut threaded connection.

Further, the adjusting part includes two sliding blocks, two the sliding block slides respectively and sets up on the rack that connecting portion corresponded, and two sliding blocks are located the both sides of connecting portion, two threaded connection has a fastening bolt on the sliding block respectively.

Furthermore, a lantern ring is sleeved on the rotating pipe, and the sliding part is fixedly connected to the inner peripheral side of the lantern ring.

Furthermore, the driving unit is an air cylinder, a hydraulic cylinder or an electric push rod and is arranged on the rack.

In the technical scheme, the driving unit drives the sliding part to reciprocate, when the single-pass movement distance of the sliding part is equal to the distance between the two arc-shaped depressions along the axial direction of the rotating pipe (if the axial direction of the rotating pipe is vertical, the distance is the height difference between the two arc-shaped depressions), the sliding part drives the rotating pipe to continuously rotate through the driving groove, and the rotating pipe drives the spray head to continuously rotate along the same direction through the grouting pipe, so that the spray head can spray slurry; when the single-pass movement distance of the sliding part is smaller than the distance between the two ends of the long axis of the cylindrical groove along the axial direction of the rotating pipe (if the axial line of the rotating pipe is vertical, the distance is the height difference between the two ends of the long axis of the cylindrical groove), the sliding part drives the rotating pipe to swing and rotate in a reciprocating manner through the driving groove, and the rotating pipe drives the spray head to swing and rotate in a reciprocating manner through the grouting pipe, so that the spray head swings and sprays slurry; when the one-way movement distance of the sliding part is zero, namely the driving unit does not drive the sliding part to move, the fixed slurry spraying of the spray head can be realized. The invention can adjust the rotating, swinging and fixed spraying of the spray head only by adjusting the stroke of the reciprocating motion of the sliding part, can adjust the swinging and spraying angle of the spray head in the swinging and spraying process, and has very convenient operation, compact structure and high practicability.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

Fig. 1-2 are schematic diagrams of the overall structure of the rotary spraying process according to the embodiment of the present invention;

FIG. 3 is a schematic view of an overall structure of a fixed-time spraying apparatus according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of an overall structure provided in another embodiment of the present invention;

FIGS. 5-6 are schematic structural views of a rotary tube and a driving slot according to an embodiment of the present invention;

FIG. 7 is a schematic structural view of a sliding portion and a collar according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of a rack and a driving mechanism according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a driving unit according to an embodiment of the present invention;

fig. 10 is a schematic structural diagram of an adjusting assembly according to an embodiment of the present invention.

Description of reference numerals:

1. a frame; 2. a grouting pipe; 3. a spray head; 4. a drive mechanism; 4.1, a speed reducing motor; 4.2, a transmission component; 4.21, shaft rod; 4.22, a first gear; 4.23, a second gear; 4.3, a chain; 4.4, a first chain wheel; 4.5, a second chain wheel; 5. rotating the tube; 6. a drive slot; 6.1, an oval groove; 6.2, arc-shaped depression; 7. a sliding part; 8. a drive unit; 8.1, intermittent gear; 8.2, a rack; 8.3, a sliding bracket; 8.4, a connecting part; 8.5, adjusting the component; 8.51, rotating rod; 8.52, a sliding block; 8.53, nut; 8.54, fastening bolts; 9. a guide bar; 10. a slider; 11. a collar; 12. and (6) rotating the ring.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

Referring to fig. 1-10, an open mine side slope water seepage treatment device provided by an embodiment of the present invention includes a rack 1, a grouting pipe 2, a driving mechanism 4, a rotating pipe 5 and a sliding portion 7, wherein the grouting pipe 2 is slidably disposed on the rack 1, the circumferential bottom of the grouting pipe 2 is communicated with a nozzle 3, the driving mechanism 4 is disposed on the rack 1 and is used for driving the grouting pipe 2 to slide on the rack 1, the rotating pipe 5 is slidably sleeved on the grouting pipe 2 along the axial direction of the grouting pipe 2, the rotating pipe 5 is rotatably connected to the rack 1, the circumferential side of the rotating pipe 5 is circumferentially provided with an inclined elliptical groove 6.1, two ends of the major axis of the elliptical groove 6.1 are respectively communicated with an arcuate recess 6.2 deviating from the major axis thereof, the two arcuate recesses 6.2 are symmetrical with respect to the center of the elliptical groove 6.1, the elliptical groove 6.1 and the two arcuate recesses 6.2 form a driving groove 6 (see fig. 5-6), the sliding part 7 is slidably connected in the driving groove 6, and the driving unit 8 is used for driving the sliding part 7 to reciprocate along the axial direction of the rotating pipe 5.

Specifically, frame 1 is as fixed basis in the use, relative side slope, ground are fixed, slip setting is gone up for frame 1 to slip in slip pipe 2, preferably, fixedly connected with guide bar 9 on frame 1, sliding connection has slider 10 on guide bar 9, slip pipe 2 rotates and connects on slider 10, the top intercommunication of slip pipe 2 has the pipeline of supply thick liquid, the thick liquid passes through the pipeline and spouts from shower nozzle 3 behind slip pipe 2, shower nozzle 3 is located slip pipe 2 bottom, the jet direction of shower nozzle 3 is perpendicular with the axial of slip pipe 2, the preferred 2-6 of shower nozzle 3 quantity. The last rotation of Z rotating tube 5 is connected with swivel becket 12, swivel becket 12 fixed connection is to frame 1, rotating tube 5 slides the cover and establishes on slip casting pipe 2, make slip casting pipe 2 and rotating tube 5 between only can the relative axial slip, unable rotation between the two, the drive groove 6 that sets up on rotating tube 5 is closed loop configuration, including oval groove 6.1 and two arc sunken 6.2, the center in oval groove 6.1 is located the axis of rotating tube 5, the both ends in oval groove 6.1 major axis are located the week side of rotating tube 5, the minor axis both ends in oval groove 6.1 are located the both ends of the diameter that passes through oval groove 6.1 center of rotating tube 5. The driving unit 8 drives the sliding part 7 to reciprocate along the axial direction of the rotating pipe 5, that is, the sliding part 7 is arranged along the axial movement of the rotating pipe 5, further, a sleeve ring 11 is sleeved on the rotating pipe 5, the sliding part 7 is fixedly connected to the inner peripheral side of the sleeve ring 11, the sliding part 7 is slidably arranged in the driving groove 6, and the sleeve ring 11 is arranged to enable the sliding part 7 to be stably and slidably connected with the driving groove 6. The drive unit 8 is mounted on the frame 1, preferably an air cylinder, a hydraulic cylinder or an electric push rod (see fig. 4).

In the technical scheme, the driving unit 8 drives the sliding part 7 to reciprocate, when the single-pass movement distance of the sliding part 7 is smaller than the distance between the two ends of the long axis of the cylindrical groove along the axis direction of the rotating pipe 5 (the distance is the linear distance between two vertical lines which are respectively made at the two ends of the long axis of the cylindrical groove towards the axis of the rotating pipe 5 and two vertical feet; if the axis of the rotating pipe 5 is vertical, the distance is the height difference between the two ends of the long axis of the cylindrical groove), the sliding part 7 slides in the section between the two ends of the long axis of the elliptical groove 6.1 during the period to enable the rotating pipe 5 to rotate, the sliding part 7 drives the rotating pipe 5 to rotate reversely when returning, so that the sliding part 7 which reciprocates drives the rotating pipe 5 to rotate (namely to oscillate), the rotating pipe 5 drives the grouting pipe 2 and the spray head 3 to oscillate reciprocally, making the spray head 3 swing to spray the slurry; when the single-pass movement distance of the sliding part 7 is equal to the distance between the two arc-shaped recesses 6.2 along the axial direction of the rotating tube 5 (the distance is the straight line distance between the two arc-shaped recesses 6.2 which are perpendicular to the axial line of the rotating tube 5 respectively and the height difference between the two arc-shaped recesses 6.2 when the axial line of the rotating tube 5 is vertical), initially, the sliding part 7 slides in one section between the two ends of the long axis of the elliptical groove 6.1, so that the rotating tube 5 rotates, when the sliding part 7 slides to one end of the long axis of the elliptical groove 6.1, the sliding direction of the sliding part 7 is not changed and continues to slide into the corresponding arc-shaped recess 6.2, then the sliding direction of the sliding part 7 is changed to the opposite direction (namely, the single-pass movement of the sliding part 7 is finished and slides back), and the sliding part 7 slides into the other section between the two ends of the long axis of the elliptical groove 6.1, the rotating pipe 5 continues to rotate along the original direction, after the sliding part 7 slides through the other end of the long axis of the elliptical groove 6.1 and enters the other arc-shaped recess 6.2, the sliding part 7 changes the sliding direction again and turns around to slide into the section between the two ends of the long axis of the initial elliptical groove 6.1, so that the sliding part 7 which does reciprocating linear motion slides circularly in the driving groove 6 to enable the rotating pipe 5 to rotate continuously along the same direction, and the rotating pipe 5 drives the grouting pipe 2 and the spray head 3 to rotate synchronously, so that the spray head 3 can spray grout; when the single-pass movement distance of the sliding portion 7 is 0, that is, when the driving unit 8 does not drive the sliding portion 7 to move, the fixed slurry ejection from the head 3 can be realized. The invention can adjust the rotary spraying, the swing spraying and the fixed spraying of the spray head 3 only by adjusting the stroke of the reciprocating motion of the sliding part 7, can adjust the swing spraying angle of the spray head 3 in the swing spraying process, and has very convenient operation, compact structure and high practicability.

As a preferred technical solution of this embodiment, the driving mechanism 4 includes a speed reduction motor 4.1, a transmission assembly 4.2, a chain 4.3, a first chain wheel 4.4 and a second chain wheel 4.5, the speed reduction motor 4.1 drives the first chain wheel 4.4 to rotate through the transmission assembly 4.2, the second chain wheel 4.5 is rotatably connected to one end of the guide rod 9 away from the frame 1, the chain 4.3 is engaged and sleeved on the first chain wheel 4.4 and the second chain wheel 4.5, the chain 4.3 is not in a closed loop shape, belongs to a drag chain and has two open ends, and both open ends of the chain 4.3 are fixedly connected to the sliding member 10. The speed reducing motor 4.1 drives the first chain wheel 4.4 to rotate through the transmission assembly 4.2, the first chain wheel 4.4 and the second chain wheel 4.5 are matched to drive the chain 4.3 to move, so that the sliding piece 10 is pulled upwards through the chain 4.3, the sliding piece 10 slides upwards along the guide rod 9, and the sliding piece 10 drives the grouting pipe 2 to move upwards, so that the grouting pipe 2 is lifted from a drilled hole; on the contrary, gear motor 4.1 antiport can make chain 4.3 draw slider 10 downwards and make slip casting pipe 2 insert in the drilling, perhaps, slip casting pipe 2 relies on its gravity to insert downtheholely in the slip casting, need not actuating mechanism 4 and provides power, only needs actuating mechanism 4 to carry out the driven cooperation of adaptability can.

Further preferably, the transmission assembly 4.2 includes a shaft lever 4.21, a first gear 4.22 and a second gear 4.23, the shaft lever 4.21 is rotatably connected to the guide rod 9, the first gear 4.22 and the first chain wheel 4.4 are both coaxially and fixedly connected to the shaft lever 4.21, the second gear 4.23 is coaxially and fixedly connected to the rotating shaft of the speed reduction motor 4.1, the speed reduction motor 4.1 drives the second gear 4.23 to rotate, the second gear 4.23 drives the first gear 4.22 to rotate, the first gear 4.22 drives the shaft lever 4.21 to rotate, so as to drive the first chain wheel 4.4 to rotate through the shaft lever 4.21. Preferably, transmission assembly 4.2 includes axostylus axostyle 4.21, first band pulley, second band pulley and belt, axostylus axostyle 4.21 rotates and connects on guide bar 9, first band pulley, the equal coaxial fixed connection of first sprocket 4.4 is on axostylus axostyle 4.21, the coaxial fixed connection of second band pulley is in gear motor 4.1's pivot, the belt cover is located on first band pulley and the second band pulley, gear motor 4.1 drives the second band pulley and rotates, first band pulley passes through the belt and drives first band pulley and rotate, thereby realize that first band pulley passes through axostylus axostyle 4.21 and drives first sprocket 4.4 and rotate.

As a preferred technical solution of the present embodiment, the driving unit 8 includes an intermittent gear 8.1, two racks 8.2, a sliding support 8.3, a connecting portion 8.4 and an adjusting assembly 8.5, the intermittent gear 8.1 is coaxially and fixedly connected to the shaft 4.21, the sliding support 8.3 is slidably connected to the guide rod 9, the sliding support 8.3 is fixedly connected to the two racks 8.2, the two racks 8.2 are parallel and level to the guide rod 9, the two racks 8.2 are located at two opposite sides of the circumference of the intermittent gear 8.1, the teeth of the two racks 8.2 face the circumference of the intermittent gear 8.1, one half circumference of the intermittent gear 8.1 has continuous teeth, the other half circumference is a smooth arc surface, the intermittent gear 8.1 can only mesh with the two racks 8.2 alternately during the rotation, i.e. the intermittent gear 8.1 can mesh with one rack 8.2 at any time node and necessarily mesh with one rack 8.2, the intermittent gear 8.1 cannot mesh with the two racks 8.2 at the same time, when the middle part of the tooth part of the intermittent gear 8.1 is meshed with the middle part of the rack 8.2, the sliding part 7 connected with the connecting part 8.4 is positioned at the end part of the short shaft of the elliptical groove 6.1, in the process that the driving mechanism 4 drives the grouting pipe 2 to lift, the intermittent gear 8.1 is driven by the shaft rod 4.21 to rotate, the intermittent gear 8.1 drives the rack 8.2 meshed with the intermittent gear to move along the guide rod 9 through the sliding bracket 8.3, the other rack 8.2 also synchronously moves along with the sliding bracket 8.3, when the intermittent gear 8.1 is meshed with one rack 8.2 in the rotating process, the other rack 8.2 is immediately meshed, so that the two racks 8.2 are driven to start to move reversely, the two racks 8.2 continuously do linear reciprocating motion in such a way, the distance of the intermittent gear 8.1 and one rack 8.2 from starting to meshing to driving the rack 8.2 to finishing is equal to the distance of the two arc-shaped depressions 6.2 along the axial direction of the rotating pipe 5 (the distance is the axial line of the two arc depressions 6.2 respectively, the linear distance between the two drop feet; if the axis of the rotating pipe 5 is vertical, the height difference between the two arc-shaped depressions 6.2) is obtained.

One end of the connecting part 8.4 is fixedly connected with the sliding part 7, the other end of the connecting part is connected with one of the racks 8.2 in a sliding mode, and the adjusting component 8.5 is used for adjusting the sliding stroke of the connecting part 8.4 on the corresponding rack 8.2. If the adjusting component 8.5 adjusts the sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 to 0 (as shown in fig. 1), that is, the adjusting component 8.5 makes the connecting part 8.4 unable to slide on the corresponding rack 8.2, the connecting part 8.4 is relatively fixed with the corresponding rack 8.2, when the rack 8.2 makes a linear reciprocating motion, the rack 8.2 drives the connecting part 8.4 and the sliding part 7 to move synchronously, so that the sliding part 7 slides circularly in the driving groove 6 to make the rotating pipe 5 rotate continuously along the same direction, and the rotating pipe 5 drives the grouting pipe 2 and the nozzle 3 to rotate synchronously, so that the nozzle 3 makes the nozzle 3 spray grout; if the adjusting component 8.5 adjusts the sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 to the maximum, namely the adjusting component 8.5 enables the single-pass sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 to be equal to or larger than the distance between the two arc-shaped depressions 6.2 along the axis direction of the rotating pipe 5 (the distance is the linear distance between the two arc-shaped depressions 6.2 and the two vertical feet when the axis of the rotating pipe 5 is vertical, namely the height difference between the two arc-shaped depressions 6.2, as shown in fig. 3), when the rack 8.2 makes linear reciprocating motion, the rack 8.2 slides relative to the connecting part 8.4, the rack 8.2 cannot drive the connecting part 8.4 to move, the sliding part 7 cannot follow the rack 8.2 to move, so that the rotating pipe 5 cannot rotate, the grouting pipe 2 and the spray head 3 cannot rotate in the lifting process, and the spray head 3 is used for spraying grout; if the adjusting component 8.5 adjusts the sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 to be larger than 0 and smaller than the distance between the two ends of the long axis of the cylindrical groove along the axis of the rotating tube 5 (the distance is the straight line distance between the two vertical feet and the straight line distance between the two ends of the long axis of the cylindrical groove respectively making vertical lines to the axis of the rotating tube 5; and if the axis of the rotating tube 5 is vertical, the distance is the height difference between the two ends of the long axis of the cylindrical groove), as shown in fig. 9-10, when the rack 8.2 makes straight line reciprocating motion, the rack 8.2 starts to slide relative to the connecting part 8.4, the connecting part 8.4 cannot be driven to move, until the sliding stroke of the connecting part 8.4 on the rack 8.2 is finished, the rack 8.2 drives the connecting part 8.4 and the sliding part 7 to move synchronously, the sliding part 7 slides in the section between the two ends of the long axis of the elliptical groove 6.1, so that the rotating tube 5 rotates, and the intermittent gear 8.1 is engaged with the rack 8.2, rack 8.2 reverse motion drives connecting portion 8.4 after 8.4 slip one end distance relative connecting portion and moves together, and sliding part 7 returns journey in drive groove 6 promptly, makes rotating tube 5 antiport to realize rotating tube 5, slip casting pipe 2 and the reciprocal pendulum commentaries on classics (reciprocating rotation) of shower nozzle 3, make shower nozzle 3 pendulum spraying liquid, further adjust connecting portion 8.4 the regulation of the angle size of spouting of shower nozzle 3 pendulum through adjusting part 8.5 in above-mentioned within range.

As a further preferable technical solution of this embodiment, referring to fig. 9, the adjusting assembly 8.5 includes a rotating rod 8.51 and two sliding blocks 8.52, the rotating rod 8.51 is rotatably connected to the sliding bracket 8.3, the two sliding blocks 8.52 are respectively slidably disposed on the rack 8.2 corresponding to the connecting portion 8.4, the two sliding blocks 8.52 are located at two sides of the connecting portion 8.4, a nut 8.53 is respectively connected to the two sliding blocks 8.52, the two nuts 8.53 are coaxial and have opposite internal threads, and two external threads having opposite rotation directions are disposed on the rotating rod 8.51, so that the rotating rod 8.51 is respectively in threaded connection with the two nuts 8.53. When the rotating rod 8.51 rotates along the first direction, the two nuts 8.53 can synchronously approach, so that the two sliding blocks 8.52 synchronously slide and approach; when the rotating rod 8.51 rotates along the second direction, the two nuts 8.53 can be synchronously separated, so that the two sliding blocks 8.52 can synchronously slide away; the first direction and the second direction are opposite rotation directions. As another preferred technical solution, referring to fig. 10, the adjusting assembly 8.5 includes two sliding blocks 8.52, the two sliding blocks 8.52 are respectively slidably disposed on the rack 8.2 corresponding to the connecting portion 8.4, the two sliding blocks 8.52 are located at two sides of the connecting portion 8.4, the two sliding blocks 8.52 are respectively connected with a fastening bolt 8.54 through threads, the corresponding sliding block 8.52 can slide on the rack 8.2 by loosening the fastening bolt 8.54, and the corresponding sliding block 8.52 can be locked on the rack 8.2 by tightening the fastening bolt 8.54, thereby realizing adjustment of the distance between the two sliding blocks 8.52.

In the above two technical solutions, the distance between the two sliding blocks 8.52 is the sliding stroke of the connecting portion 8.4 on the corresponding rack 8.2. When the two sliding blocks 8.52 synchronously slide close to and are clamped at two sides of the connecting part 8.4, namely the connecting part 8.4 is fixed relative to the rack 8.2, the sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 is 0, the driving unit 8 enables the spray head 3 to spray slurry (as shown in fig. 1); when the two sliding blocks 8.52 synchronously slide away to the maximum distance, the one-way sliding stroke of the connecting part 8.4 on the corresponding rack 8.2 is equal to or larger than the distance between the two arc-shaped recesses 6.2 along the axial direction of the rotating pipe 5 (the distance is the linear distance between two vertical feet when the two arc-shaped recesses 6.2 respectively make vertical lines to the axial line of the rotating pipe 5; if the axial line of the rotating pipe 5 is vertical, the distance is the height difference between the two arc-shaped recesses 6.2), and the driving unit 8 enables the spray head 3 to perform fixed slurry spraying (as shown in fig. 3); when the distance between the two sliding blocks 8.52 is larger than 0 and smaller than the distance between the two ends of the long axis of the cylindrical groove along the axis direction of the rotating pipe 5 (the distance is the linear distance between the two ends of the long axis of the cylindrical groove and the rotating pipe 5, respectively making vertical lines towards the axis of the rotating pipe 5, and if the axis of the rotating pipe 5 is vertical, the distance is the height difference between the two ends of the long axis of the cylindrical groove), the driving unit 8 enables the spray head 3 to swing and spray slurry (as shown in fig. 9-10), the distance between the two sliding blocks 8.52 is further adjusted within the range, and the swing spray angle of the spray head 3 can be adjusted.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (9)

1. The utility model provides a device is administered in mine side slope infiltration which characterized in that includes:

a frame;

the grouting pipe is arranged on the rack in a sliding manner, and the bottom of the periphery of the grouting pipe is communicated with a spray head;

the driving mechanism is arranged on the rack and used for driving the grouting pipe to slide on the rack;

the rotating pipe is sleeved on the grouting pipe in a sliding manner along the axial direction of the grouting pipe and is rotatably connected to the rack, an inclined elliptical groove is annularly formed in the peripheral side of the rotating pipe, two ends of the long axis of the elliptical groove are respectively communicated with an arc-shaped recess deviating from the long axis of the elliptical groove, the two arc-shaped recesses are symmetrical relative to the center of the elliptical groove, and the elliptical groove and the two arc-shaped recesses form a driving groove;

a sliding part which is connected in the driving groove in a sliding way;

and the driving unit is used for driving the sliding part to reciprocate along the axial direction of the rotating pipe.

2. The surface mine slope seepage water treatment device of claim 1, wherein a guide rod is fixedly connected to the frame, a sliding member is slidably connected to the guide rod, and the grouting pipe is rotatably connected to the sliding member.

3. The surface mine slope seepage water treatment device according to claim 2, wherein the driving mechanism comprises a speed reducing motor, a transmission assembly, a chain, a first chain wheel and a second chain wheel, the speed reducing motor drives the first chain wheel to rotate through the transmission assembly, the second chain wheel is rotatably connected to one end of the guide rod, which is far away from the rack, the chain is meshed and sleeved on the first chain wheel and the second chain wheel, and two open ends of the chain are fixedly connected to the sliding part.

4. The surface mine slope seepage water treatment device of claim 3, wherein the transmission assembly comprises a shaft rod, a first gear and a second gear, the shaft rod is rotatably connected to the guide rod, the first gear and the first chain wheel are coaxially and fixedly connected to the shaft rod, and the second gear is coaxially and fixedly connected to a rotating shaft of the speed reduction motor.

5. The surface mine slope seepage water treatment device according to claim 4, wherein the driving unit comprises an intermittent gear, two racks, a sliding support, a connecting part and an adjusting component, the intermittent gear is coaxially and fixedly connected to the shaft rod, the sliding support is slidably connected to the guide rod, the sliding support is fixedly connected with the two racks, the two racks are parallel to the guide rod, the two racks are located on two opposite sides of the circumferential direction of the intermittent gear, the intermittent gear is alternately meshed with the two racks in the rotating process, one end of the connecting part is fixedly connected with the sliding part, the other end of the connecting part is slidably connected with one of the racks, and the adjusting component is used for adjusting the sliding stroke of the connecting part on the corresponding rack.

6. The surface mine side slope seepage treatment device according to claim 5, wherein the adjusting assembly comprises a rotating rod and two sliding blocks, the rotating rod is rotatably connected to the sliding support, the two sliding blocks are respectively slidably arranged on the racks corresponding to the connecting portions, the two sliding blocks are located on two sides of the connecting portions, a nut is respectively connected to the two sliding blocks, the two nuts are coaxial, the internal threads of the nuts are opposite in rotation direction, and two sections of external threads with opposite rotation directions are arranged on the rotating rod, so that the rotating rod is respectively in threaded connection with the two nuts.

7. The surface mine slope seepage water treatment device according to claim 5, wherein the adjusting assembly comprises two sliding blocks, the two sliding blocks are respectively slidably arranged on the corresponding racks of the connecting part, the two sliding blocks are positioned on two sides of the connecting part, and a fastening bolt is respectively in threaded connection with the two sliding blocks.

8. The surface mine slope seepage water treatment device according to claim 1, wherein a lantern ring is sleeved on the rotating pipe, and the sliding part is fixedly connected to the inner peripheral side of the lantern ring.

9. The surface mine slope seepage water treatment device of claim 1, wherein the driving unit is a cylinder, a hydraulic cylinder or an electric push rod, and is mounted on the frame.

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