CN-116877846-B - Simulation platform mounting device and method for carrying high-frequency ADCP

CN116877846BCN 116877846 BCN116877846 BCN 116877846BCN-116877846-B

Abstract

The invention discloses a simulation platform mounting device and method for carrying high-frequency ADCP, relating to the technical field of simulation platform equipment, comprising a support, the inside of support is provided with emulation platform body, high frequency ADCP, two-way limiting mechanism, support the end subassembly, protection auxiliary member are installed on the top of emulation platform body. According to the simulation platform, the bidirectional limiting mechanism and the bottom supporting assembly are arranged, the bidirectional screw rod is driven to rotate by the rotary swinging disc, the rectangular clamping block is driven to clamp the outer wall of the simulation platform body, when the first hydraulic cylinder output end drives the pulling seat to drive the simulation platform body to move upwards for a certain distance through the rectangular clamping block, the driving motor output end drives the swinging block to drive the bottom supporting disc to rotate for one hundred eighty degrees and attach to the bottom end of the simulation platform body, so that the simulation platform body is supported, a worker can conveniently and rapidly move the simulation platform body to a designated position to fix the simulation platform body, the efficiency of the worker during installation is improved, and the worker can conveniently operate the simulation platform body.

Inventors

YANG LEI
SU YUMIN
SU GUANGSHENG

Assignees

哈尔滨工程大学

Dates

Publication Date: 20260505
Application Date: 20230407

Claims (10)

1. The utility model provides a carry on simulation platform installation device of high frequency ADCP, includes support (1), its characterized in that, the inboard of support (1) is provided with simulation platform body (9), high frequency ADCP (10) are installed on the top of simulation platform body (9), be provided with two-way limiting mechanism between support (1) inboard and simulation platform body (9), the inboard of support (1) is provided with pulls seat (2), the front end that pulls seat (2) is provided with rectangle clamp block (8), the bottom of rectangle clamp block (8) is provided with holds in the palm the end subassembly, the top fixedly connected with second pneumatic cylinder (4) of support (1), the output fixedly connected with protection auxiliary member of second pneumatic cylinder (4), the bottom fixedly connected with of support (1) a plurality of second universal wheels (48); The bidirectional limiting mechanism comprises a first hydraulic cylinder (3) fixedly connected to the top end of the support (1), the output end of the first hydraulic cylinder (3) penetrates through the inner side of the support (1) and is fixedly connected with the pulling seat (2), the inner side of the pulling seat (2) is rotationally connected with a bidirectional screw rod (11), one end of the bidirectional screw rod (11) penetrates through the outer side of the pulling seat (2) and is fixedly connected with a swinging disc (30), one end of the rectangular clamping block (8) is fixedly connected with a first rectangular sliding block (14), the first rectangular sliding block (14) is sleeved on the outer wall of the bidirectional screw rod (11), and the rectangular clamping block (8) and the top end of the pulling seat (2) are provided with compression auxiliary components.
2. The simulation platform mounting device for carrying high-frequency ADCP according to claim 1, wherein two rectangular clamping blocks (8) are arranged, the outer wall of the bidirectional screw rod (11) is provided with positive and negative threads, the two rectangular clamping blocks (8) are respectively sleeved on the positive and negative thread outer walls of the bidirectional screw rod (11) through first rectangular sliding blocks (14) fixedly connected with one end, and two guide grooves matched with the first rectangular sliding blocks (14) are formed in the inner side of the pulling seat (2).
3. The simulation platform mounting device for carrying high-frequency ADCP according to claim 1, wherein the support base assembly comprises a swinging block (25) rotatably connected to the bottom end of the rectangular clamping block (8), a driving motor (26) is mounted at the bottom end of the rectangular clamping block (8), an output end of the driving motor (26) is fixedly connected with the swinging block (25), one end of the swinging block (25) is fixedly connected with a support base plate (12), and a first universal wheel (13) is mounted at the top end of the support base plate (12).
4. The simulation platform mounting device for carrying high-frequency ADCP according to claim 3, wherein the compression auxiliary assembly comprises a second rectangular upright post (18) fixedly connected to the top end of the pulling seat (2), a power block (19) is slidably connected to the top end of the second rectangular upright post (18), a first compression spring (20) is fixedly connected to the bottom end of the power block (19) on the outer wall of the second rectangular upright post (18), the bottom end of the first compression spring (20) is fixedly connected to the pulling seat (2), an inward concave rectangular pressing groove (24) is formed in the top end of the rectangular clamping block (8), a rectangular pressing block (23) is fixedly connected to the top of the rectangular pressing groove (24), and a pulling unit is arranged on the outer wall of one side of the power block (19) and the outer wall of the swinging block (25).
5. The simulation platform mounting device for carrying high-frequency ADCP according to claim 4, wherein the pulling unit comprises a winding rod (27) fixedly connected to one side outer wall of the swinging block (25), one end of the winding rod (27) penetrates through the outside of the rectangular clamping block (8) and is rotationally connected with the rectangular clamping block (8), the outer wall of the winding rod (27) is wound with a pulling rope (15), an inclined block (28) is fixedly connected to the outer wall of the rectangular clamping block (8), a fixed guide wheel (29) is rotationally connected to the inner side of the inclined block (28), the pulling rope (15) is attached to the outer wall of the fixed guide wheel (29), a T-shaped block (21) is fixedly connected to one side outer wall of the power block (19), a rectangular (17) is slidably connected to the outer wall of the T-shaped block (21), a rectangular stand column (16) is fixedly connected to the top end of the rectangular clamping block (8), and the first rectangular stand column (16) is fixedly connected to the inner side of the rectangular slide rod (17) and penetrates through the rectangular stand column (22).
6. The simulation platform mounting device for carrying high-frequency ADCP according to claim 1, wherein the protection auxiliary piece comprises an L-shaped pressing seat (5) fixedly connected with the output end of the second hydraulic cylinder (4), an L-shaped pressing block (6) is fixedly connected with the bottom end of the L-shaped pressing seat (5), a third rectangular sliding block (40) is fixedly connected with the inner side of the L-shaped pressing seat (5), the third rectangular sliding block (40) is in sliding connection with the support (1), second rectangular sliding grooves (41) are formed in the outer walls of the two sides of the support (1), the third rectangular sliding block (40) are arranged in the second rectangular sliding grooves (41), auxiliary double-pressing components extending to the inner side of the L-shaped pressing block (6) are arranged on the outer walls of the two sides of the L-shaped pressing block (6), and locking units are arranged at one end of the pulling seat (2) and the top end of the L-shaped pressing block (6).
7. The simulation platform mounting device for carrying high-frequency ADCP according to claim 6, wherein the auxiliary double-pressure assembly comprises a rotary press block (7) which is rotatably connected to the inner side of an L-shaped press block (6), a rotary shaft (45) is fixedly connected to one side outer wall of the rotary press block (7), one end of the rotary shaft (45) penetrates to the inner side of the L-shaped press block (6) and is fixedly connected with a second spur gear (46), the inner side of the L-shaped press block (6) is slidably connected with a T-shaped slide bar (43), the bottom end of the T-shaped slide bar (43) penetrates to the bottom end of the L-shaped press block (6), a second compression spring (44) is fixedly connected to the outer wall of the T-shaped slide bar (43), one end of the second compression spring (44) is fixedly connected with the L-shaped press block (6), two side outer walls of the T-shaped slide bar (43) are fixedly connected with third spur racks (47), the third spur racks (47) are meshed with the second spur gears (46), and threaded holes (42) are formed in the inner side of the L-shaped press block (6).
8. The simulation platform mounting device for carrying high-frequency ADCP according to claim 6, wherein the enclasping locking unit comprises an L-shaped vertical rod (31) fixedly connected to the top end of an L-shaped pressing block (6), one end of the L-shaped vertical rod (31) is fixedly connected with a first semi-enclasping block (32) above the swinging disc (30), one side outer wall of the L-shaped vertical rod (31) is fixedly connected with a first straight rack (33), one end of the pulling seat (2) is rotationally connected with a rotating shaft (34), the outer wall of the rotating shaft (34) is fixedly connected with a first straight gear (35), the first straight gear (35) is meshed with the first straight rack (33), a second semi-enclasping block (36) is arranged below the swinging disc (30), the bottom end of the second semi-enclasping block (36) is fixedly connected with a second straight rack (37), and the second straight rack (37) is meshed with the first straight rack (35).
9. The simulation platform mounting device for carrying high-frequency ADCP according to claim 8, wherein a first rectangular sliding groove (39) is formed in one end of the pulling seat (2), a second rectangular sliding block (38) is fixedly connected to the inner side of the second straight rack (37), the second rectangular sliding block (38) is in sliding connection with the pulling seat (2), and the second rectangular sliding block (38) is arranged in the first rectangular sliding groove (39) and is matched with the first rectangular sliding groove (39).
10. A simulation platform installation method for carrying high-frequency ADCP, characterized in that a simulation platform installation device for carrying high-frequency ADCP according to any one of claims 1 to 9 is adopted, comprising the following steps: S1, when the simulation platform body (9) needs to be mounted at a designated position, firstly, moving the support (1) to the designated position, then manually rotating the wobble plate (30) by a worker to drive the bidirectional screw rod (11) to rotate, so as to drive two first rectangular sliding blocks (14) to respectively drive one rectangular clamping block (8) to approach the simulation platform body (9), and when the two rectangular clamping blocks (8) are clamped on the outer wall of the simulation platform body (9) to fix the two rectangular clamping blocks with the pulling seat (2); s2, attaching the support to the ground through a protection auxiliary piece to support the support (1); S3, starting the first hydraulic cylinder (3), wherein the output end of the first hydraulic cylinder (3) drives the pulling seat (2) to drive the simulation platform body (9) to move upwards through the rectangular clamping block (8), and when the simulation platform body (9) moves upwards for a certain distance, the simulation platform body (9) is supported on the ground through the bottom supporting assembly to be supported.

Description

Simulation platform mounting device and method for carrying high-frequency ADCP Technical Field The invention relates to the field of simulation platforms, in particular to a device and a method for installing a simulation platform carrying high-frequency ADCP. Background Simulation is to reproduce the intrinsic process occurring in the actual system by using a model, and to study the existing or designed system through experiments on a system model, which is also called simulation, and includes various models of physics and mathematics, static and dynamic, continuous and discrete, and a special simulation platform is needed in the process of simulating or testing the high-frequency ADCP. The existing simulation platform carrying the high-frequency ADCP generally has larger volume, and the simulation platform carrying the high-frequency ADCP needs to be continuously adjusted by staff in the process of being installed at a designated position, therefore, the simulation platform mounting device and method for mounting the high-frequency ADCP are provided for solving the problems. Disclosure of Invention The invention aims to provide a simulation platform mounting device and method for carrying high-frequency ADCP in order to solve the problem that the simulation platform carrying high-frequency ADCP is troublesome in the mounting process. The simulation platform mounting device comprises a support, wherein a simulation platform body is arranged on the inner side of the support, a high-frequency ADCP is mounted on the top end of the simulation platform body, a bidirectional limiting mechanism is arranged between the inner side of the support and the simulation platform body, a pulling seat is arranged on the inner side of the support, a rectangular clamping block is arranged at the front end of the pulling seat, a bottom supporting assembly is arranged at the bottom end of the rectangular clamping block, a second hydraulic cylinder is fixedly connected to the top end of the support, a protection auxiliary piece is fixedly connected to the output end of the second hydraulic cylinder, and a plurality of second universal wheels are fixedly connected to the bottom end of the support; The bidirectional limiting mechanism comprises a first hydraulic cylinder fixedly connected to the top end of the support, the output end of the first hydraulic cylinder penetrates through the inner side of the support and is fixedly connected with the pulling seat, the inner side of the pulling seat is rotationally connected with a bidirectional screw rod, one end of the bidirectional screw rod penetrates through the outer side of the pulling seat and is fixedly connected with a swinging disc, one end of the rectangular clamping block is fixedly connected with a first rectangular sliding block, the first rectangular sliding block is sleeved on the outer wall of the bidirectional screw rod, and the rectangular clamping block and the top end of the pulling seat are provided with compression auxiliary assemblies. As a still further scheme of the invention, two rectangular clamping blocks are arranged, the outer wall of the bidirectional screw rod is provided with positive and negative threads, the two rectangular clamping blocks are respectively sleeved on the outer walls of the positive threads and the negative threads of the bidirectional screw rod through first rectangular sliding blocks with one ends fixedly connected, and two guide grooves matched with the first rectangular sliding blocks are formed in the inner side of the pulling seat. As a still further scheme of the invention, the bottom supporting assembly comprises a swinging block rotatably connected to the bottom end of the rectangular clamping block, a driving motor is arranged at the bottom end of the rectangular clamping block, the output end of the driving motor is fixedly connected with the swinging block, one end of the swinging block is fixedly connected with a bottom supporting plate, and the top end of the bottom supporting plate is provided with a first universal wheel. As a still further scheme of the invention, the compression auxiliary assembly comprises a second rectangular upright post fixedly connected to the top end of the pulling seat, a power block is slidably connected to the top end of the second rectangular upright post, a first compression spring is fixedly connected to the outer wall of the second rectangular upright post at the bottom end of the power block, the bottom end of the first compression spring is fixedly connected with the pulling seat, an inward concave rectangular pressing groove is formed in the top end of the rectangular clamping block, a rectangular pressing block is fixedly connected to the top end of the power block above the rectangular pressing groove, and a pulling unit is arranged on the outer wall of one side of the power block and the outer wall of the swinging block. The pulling unit comprises a winding rod fixedly connected