CN214143551U

CN214143551U - Hydraulic engineering slope bearing structure

Info

Publication number: CN214143551U
Application number: CN202023098110.6U
Authority: CN
Inventors: 单艳霞
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-09-07
Anticipated expiration: 2030-12-22

Abstract

The utility model provides a hydraulic engineering bank protection bearing structure. The hydraulic engineering slope protection supporting structure comprises a bottom plate; the two supporting plates are fixedly arranged on the top of the bottom plate; the first motor is fixedly arranged at the top of the bottom plate; the two-way screw rods are rotatably arranged on the two support plates; the two synchronous wheels are respectively and fixedly sleeved on the output shaft of the first motor and the bidirectional screw; the synchronous belt is sleeved on the two synchronous wheels; the two bearing plates are arranged on the top of the bottom plate in a sliding mode, and the bidirectional screw penetrates through the two bearing plates and is in threaded connection with the two bearing plates. The utility model provides a hydraulic engineering slope protection bearing structure has application scope extensively, and the cost of manufacture is low, the higher advantage of mobility.

Description

Hydraulic engineering slope bearing structure

Technical Field

The utility model relates to a hydraulic engineering technical field especially relates to a hydraulic engineering slope bearing structure.

Background

The rapid advance of urbanization construction makes ecological environment worsen day by day, and especially water pollution becomes more and more serious, consequently must strengthen hydraulic engineering construction, can reduce soil erosion and water loss, maintains ecological balance, for making dyke engineering firm, need carry out the bank protection among the hydraulic engineering, nevertheless because the water extremely easily causes soil erosion and water loss to the washing of bank protection, just need support the protection to the bank protection this moment.

However, the existing slope protection supporting structure generally adopts an integral pouring structure, the whole slope protection engineering quantity is large, the investment cost is high for temporary soil slope supporting work, and the maneuverability is slightly insufficient.

Therefore, it is necessary to provide a new support structure for slope protection of hydraulic engineering to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem provide an application scope is wide, and the cost of manufacture is low, the higher hydraulic engineering bank protection bearing structure of mobility.

For solving the technical problem, the utility model provides a hydraulic engineering slope protection bearing structure includes: a base plate; the two supporting plates are fixedly arranged on the top of the bottom plate; the first motor is fixedly arranged at the top of the bottom plate; the two-way screw rods are rotatably arranged on the two support plates; the two synchronous wheels are respectively and fixedly sleeved on the output shaft of the first motor and the bidirectional screw; the synchronous belt is sleeved on the two synchronous wheels; the two bearing plates are arranged at the top of the bottom plate in a sliding mode, and the bidirectional screw penetrates through the two bearing plates and is in threaded connection with the two bearing plates; the four universal wheels are all arranged at the bottom of the bottom plate; the two side plates are respectively arranged above the two bearing plates; the two fixing plates are respectively and fixedly arranged on one sides of the two side plates, which are close to each other; the two linkage rods are respectively and rotatably arranged on the two side plates; the two second motors are respectively and fixedly arranged at the tops of the two fixing plates; the two driving belt pulleys are respectively fixedly sleeved on the output shafts of the two second motors; the two driven belt pulleys are fixedly sleeved on the two linkage rods respectively; the two belts are fixedly sleeved on the corresponding driving belt pulley and the corresponding driven belt pulley; the four position-fixing plates are fixedly arranged on one sides of the two side plates, which are far away from each other; the two screws are rotatably arranged on the two corresponding retention plates; the two driving bevel gears are respectively and fixedly arranged at one ends, far away from each other, of the two linkage rods; the two driven bevel gears are fixedly sleeved on the two screw rods respectively, and the two driving bevel gears are meshed with the two driven bevel gears respectively; the two extension plates are respectively and fixedly arranged on one sides, far away from each other, of the two positioning plates positioned below; the two protection plates are respectively arranged outside one side of the two side plates away from each other, and are respectively hinged with the two extending plates; the two movable blocks are respectively installed on the two screw rods in a threaded manner; the two connecting blocks are fixedly arranged on one sides of the two protection plates, which are close to each other; the two connecting rods are hinged to the two movable blocks respectively, and one ends, far away from each other, of the two connecting rods are hinged to the two connecting blocks respectively.

Preferably, two chutes are formed in the top of the bottom plate, two sliders are slidably mounted in the chutes, and the tops of the sliders extend to the upper portion of the bottom plate and are fixedly connected with the corresponding bearing plates.

Preferably, both ends of the bidirectional screw are fixedly provided with a block, and the two blocks are respectively matched with the two bearing plates.

Preferably, first bearing holes are formed in the two supporting plates, two first bearings are sleeved on the two-way screw, and outer rings of the two first bearings are fixedly connected with the inner walls of the two first bearing holes respectively.

Preferably, the four retaining plates are respectively provided with a second bearing hole, the two screws are respectively and fixedly sleeved with two second bearings, and the inner walls of the four second bearing holes are respectively and fixedly connected with the outer rings of the four second bearings.

Preferably, third bearing holes are formed in the two side plates, the linkage rod is sleeved with third bearings, and the outer rings of the third bearings are fixedly connected with the inner walls of the third bearing holes respectively.

Preferably, the top of the two bearing plates is fixedly provided with two supporting and connecting blocks respectively, and the top of the two supporting and connecting blocks is fixedly connected with the bottom of the two side plates respectively.

Compared with the prior art, the utility model provides a hydraulic engineering slope protection bearing structure has following beneficial effect:

the utility model provides a hydraulic engineering slope protection bearing structure, when carrying out the bank protection and supporting, start first motor, two-way screw rod rotates under the transmission of synchronizing wheel, two loading boards drive two curb plates to opposite direction horizontal migration simultaneously, close first motor when the bottom of guard plate contacts the bank protection inclined plane, then start two second motors, two guard plates just can take place the angular variation, can support until guard plate and soil slope laminating mutually, when the later stage is demolishd, reverse start two second motors and first motor can, the holistic manufacturing cost of this device is lower, the cost drops into fewly, and but through angle regulation's guard plate, make this device can be applicable to the soil slope of more different gradients, can follow-up with along with tearing open, whole mobility is higher.

Drawings

Fig. 1 is a schematic structural view of a preferred embodiment of a support structure for a slope protection of a hydraulic engineering according to the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

fig. 3 is an enlarged schematic view of a portion B shown in fig. 1.

Reference numbers in the figures: 1. a base plate; 2. a support plate; 3. a first motor; 4. a synchronizing wheel; 5. a synchronous belt; 6. a bidirectional screw; 7. a universal wheel; 8. a carrier plate; 9. a slider; 10. a side plate; 11. a fixing plate; 12. a second motor; 13. a drive pulley; 14. a belt; 15. a linkage rod; 16. driving bevel gears; 17. driven bevel gears; 18. a position-retaining plate; 19. a screw; 20. an extension plate; 21. a movable block; 22. a connecting rod; 23. a joining block; 24. a protection plate; 25. a driven pulley.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural diagram of a preferred embodiment of a support structure for a hydraulic engineering slope protection according to the present invention; FIG. 2 is an enlarged view of portion A of FIG. 1; fig. 3 is an enlarged schematic view of a portion B shown in fig. 1. Hydraulic engineering bank protection bearing structure includes: a base plate 1; the two supporting plates 2 are fixedly arranged at the top of the bottom plate 1; the first motor 3 is fixedly arranged at the top of the bottom plate 1; the two-way screw rods 6 are rotatably arranged on the two support plates 2; the two synchronizing wheels 4 are respectively and fixedly sleeved on the output shaft of the first motor 3 and the bidirectional screw 6; the synchronous belt 5 is sleeved on the two synchronous wheels 4; the two bearing plates 8 are arranged on the top of the bottom plate 1 in a sliding mode, and the bidirectional screw 6 penetrates through the two bearing plates 8 and is in threaded connection with the two bearing plates 8; the four universal wheels 7 are all arranged at the bottom of the bottom plate 1; the two side plates 10 are respectively arranged above the two bearing plates 8; the two fixing plates 11 are respectively and fixedly arranged on one sides of the two side plates 10 close to each other; the two linkage rods 15 are respectively and rotatably arranged on the two side plates 10; the two second motors 12 are respectively and fixedly arranged on the tops of the two fixing plates 11; the two driving belt pulleys 13 are respectively and fixedly sleeved on the output shafts of the two second motors 12; the two driven belt pulleys 25 are respectively and fixedly sleeved on the two linkage rods 15; the two belts 14 are fixedly sleeved on the corresponding driving belt pulley 13 and the corresponding driven belt pulley 25; the four retention plates 18 are all fixedly arranged on one sides, far away from each other, of the two side plates 10; the two screw rods 19 are rotatably arranged on the two corresponding retention plates 18; the two driving bevel gears 16 are respectively and fixedly arranged at one ends, far away from each other, of the two linkage rods 15; the two driven bevel gears 17 are fixedly sleeved on the two screw rods 19 respectively, and the two driving bevel gears 16 are meshed with the two driven bevel gears 17 respectively; the two extension plates 20 are respectively and fixedly installed on one sides, far away from each other, of the two retention plates 18 positioned below; the two protection plates 24 are respectively arranged outside one side of the two side plates 10 far away from each other, and the two protection plates 24 are respectively hinged with the two extension plates 20; the two movable blocks 21 are respectively installed on the two screw rods 19 in a threaded manner; the two connecting blocks 23 are respectively fixedly arranged on one sides of the two protection plates 24, which are close to each other; two connecting rods 22, two the connecting rod 22 articulates respectively on two the movable block 21, two the one end that the connecting rod 22 kept away from each other is articulated respectively with two it links up the piece 23 mutually.

Two chutes are formed in the top of the bottom plate 1, two sliding blocks 9 are arranged in the chutes in a sliding mode, and the tops of the sliding blocks 9 extend to the upper portion of the bottom plate 1 and correspond to the bearing plate 8 in a fixed connection mode.

Two ends of the bidirectional screw 6 are fixedly provided with a block respectively, and the two blocks are respectively matched with the two bearing plates 8.

First bearing holes are formed in the two supporting plates 2, two first bearings are sleeved on the two-way screw 6, and outer rings of the two first bearings are fixedly connected with the inner walls of the two first bearing holes respectively.

The four retaining plates 18 are respectively provided with a second bearing hole, the two screw rods 19 are respectively fixedly sleeved with two second bearings, and the inner walls of the four second bearing holes are respectively fixedly connected with the outer rings of the four second bearings.

Third bearing holes are formed in the two side plates 10, a third bearing is sleeved on the linkage rod 15, and the outer ring of the third bearing is fixedly connected with the inner wall of each third bearing hole.

The top of the two bearing plates 8 is fixedly provided with two supporting blocks respectively, and the top of the two supporting blocks is fixedly connected with the bottom of the two side plates 10 respectively.

The utility model provides a hydraulic engineering slope protection bearing structure's theory of operation as follows:

when the device is used, the device is pushed to the middle of soil slopes on two sides, then the first motor 3 is started in the forward direction, the output shaft of the first motor 3 rotates, under the transmission action of the synchronous belt 5, the two synchronous wheels 4 can rotate simultaneously, the two-way screw rods 6 can rotate along with the two synchronous wheels, the two bearing plates 8 move in the direction away from each other, so that the two side plates 10 are away from each other, the first motor 3 is closed after one side of the bottom of the two protection plates 24 contacts the soil slope, then the two second motors 12 are started in the forward direction simultaneously, at the moment, the two driving belt pulleys 13 fixedly sleeved on the output shafts of the two second motors 12 rotate, through the transmission of the two belts 14, the corresponding two driven belt pulleys 25 also start to rotate, so that the two linkage rods 15 rotate, at the moment, under the meshing relationship of the driving bevel gears 16 and the driven bevel gears 17, the two screw rods 19 can rotate, at this time, through the thread relationship between the two movable blocks 21 and the two screws 19, the two movable blocks 21 move downwards, so that under the pushing of the two connecting rods 22 to the two connecting blocks 23, the two protection plates 24 make circular motion around the hinged positions of the two extension plates 20, the presented angles start to change until the two protection plates 24 are attached to the corresponding soil slope slopes, the two second motors 12 are closed, and when the device is detached, the two second motors 12 and the first motor 3 are reversely started.

the utility model provides a hydraulic engineering slope protection bearing structure, when carrying out the bank protection and supporting, start first motor 3, two-way screw rod 6 rotates under synchronizing wheel 4's transmission, two loading boards 8 drive two curb plates 10 to opposite direction horizontal migration simultaneously, close first motor 3 when the bottom of guard plate 24 contacts the bank protection slope, then start two second motors 12, two guard plates 24 just can take place the angle change, can support until guard plate 24 and the laminating of soil slope mutually, when the later stage is demolishd, reverse start two second motors 12 and first motor 3 can, the holistic manufacturing cost of this device is lower, the cost drops into fewly, and guard plate 24 through angle regulation, make this device can be applicable to the soil slope of more different gradients, can be along with tearing open along with using, whole mobility is higher.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims

1. The utility model provides a hydraulic engineering bank protection bearing structure which characterized in that includes:

a base plate;

the two supporting plates are fixedly arranged on the top of the bottom plate;

the first motor is fixedly arranged at the top of the bottom plate;

the two-way screw rods are rotatably arranged on the two support plates;

the two synchronous wheels are respectively and fixedly sleeved on the output shaft of the first motor and the bidirectional screw;

the synchronous belt is sleeved on the two synchronous wheels;

the two bearing plates are arranged at the top of the bottom plate in a sliding mode, and the bidirectional screw penetrates through the two bearing plates and is in threaded connection with the two bearing plates;

the four universal wheels are all arranged at the bottom of the bottom plate;

the two side plates are respectively arranged above the two bearing plates;

the two fixing plates are respectively and fixedly arranged on one sides of the two side plates, which are close to each other;

the two linkage rods are respectively and rotatably arranged on the two side plates;

the two second motors are respectively and fixedly arranged at the tops of the two fixing plates;

the two driving belt pulleys are respectively fixedly sleeved on the output shafts of the two second motors;

the two driven belt pulleys are fixedly sleeved on the two linkage rods respectively;

the two belts are fixedly sleeved on the corresponding driving belt pulley and the corresponding driven belt pulley;

the four position-fixing plates are fixedly arranged on one sides of the two side plates, which are far away from each other;

the two screws are rotatably arranged on the two corresponding retention plates;

the two driving bevel gears are respectively and fixedly arranged at one ends, far away from each other, of the two linkage rods;

the two driven bevel gears are fixedly sleeved on the two screw rods respectively, and the two driving bevel gears are meshed with the two driven bevel gears respectively;

the two extension plates are respectively and fixedly arranged on one sides, far away from each other, of the two positioning plates positioned below;

the two protection plates are respectively arranged outside one side of the two side plates away from each other, and are respectively hinged with the two extending plates;

the two movable blocks are respectively installed on the two screw rods in a threaded manner;

the two connecting blocks are fixedly arranged on one sides of the two protection plates, which are close to each other;

the two connecting rods are hinged to the two movable blocks respectively, and one ends, far away from each other, of the two connecting rods are hinged to the two connecting blocks respectively.

2. The hydraulic engineering slope protection supporting structure of claim 1, wherein the top of the bottom plate is provided with two sliding grooves, two sliding blocks are slidably mounted in the two sliding grooves, and the tops of the two sliding blocks extend to the upper side of the bottom plate and are fixedly connected with the corresponding bearing plates.

3. The hydraulic engineering slope protection supporting structure of claim 1, wherein two ends of the bidirectional screw are fixedly provided with two stopping blocks, and the two stopping blocks are respectively matched with the two bearing plates.

4. The hydraulic engineering slope protection supporting structure of claim 1, wherein two of the supporting plates are provided with first bearing holes, two first bearings are sleeved on the bidirectional screw rod, and outer rings of the two first bearings are respectively fixedly connected with inner walls of the two first bearing holes.

5. The hydraulic engineering slope support structure of claim 1, wherein four of the position-retaining plates are provided with second bearing holes, two of the screws are fixedly sleeved with two second bearings, and inner walls of the four second bearing holes are fixedly connected with outer rings of the four second bearings respectively.

6. The hydraulic engineering slope protection supporting structure of claim 1, wherein third bearing holes are formed in each of the two side plates, third bearings are sleeved on each of the two linkage rods, and outer rings of the two third bearings are fixedly connected with inner walls of the two third bearing holes respectively.

7. The hydraulic engineering slope protection supporting structure of claim 1, wherein two supporting blocks are fixedly installed at the tops of the two bearing plates respectively, and the tops of the two supporting blocks are fixedly connected with the bottoms of the two side plates respectively.