CN113310798B

CN113310798B - Tensile detection device for ship mooring rope

Info

Publication number: CN113310798B
Application number: CN202110517808.7A
Authority: CN
Inventors: 董红飞
Original assignee: Yancheng Shenli Ropes Mfg Co ltd
Current assignee: Yancheng Shenli Ropes Mfg Co ltd
Priority date: 2021-05-12
Filing date: 2021-05-12
Publication date: 2024-03-29
Anticipated expiration: 2041-05-12
Also published as: CN113310798A

Abstract

The invention discloses a tensile detection device for ship mooring ropes, which comprises a mounting base, supporting frames, lower clamping assemblies, upper clamping assemblies and a mobile station, wherein the supporting frames are respectively arranged on the left side and the right side of the top of the mounting base, the lower clamping assemblies are arranged above the mounting base, the upper clamping assemblies are arranged above the two supporting frames, the top frames are arranged on the tops of the supporting frames, a buffer plate is arranged below the top frames through telescopic rods, a plurality of second springs are arranged between the buffer plate and the top frames, and the mobile station is arranged on the right side of the mounting base. This tensile detection device of boats and ships hawser is provided with the buffer board, when the device breaks unqualified rope, because inertial effect, goes up the mounting bracket and can continue the upward movement, strikes and upward movement with the buffer board, under the effect of second spring, prevents to go up the direct percussion device top of mounting bracket, causes rocking and empting of device, and then improves the security of device.

Description

Tensile detection device for ship mooring rope

Technical Field

The invention relates to the technical field of cable detection, in particular to a tensile detection device for ship cables.

Background

The ship has the advantages of corrosion resistance, mildew resistance, worm damage resistance and the like besides light specific gravity, high strength and good impact resistance and wear resistance, for example, the strength and wear resistance of the nylon cable are several times that of the hemp and cotton cables, the specific gravity of the polypropylene cable is less than that of water, and the polypropylene cable can float on the water surface and is convenient and safe to operate.

Therefore, when the ship is produced to take the rope, the detection of the tensile property is an indispensable step, the strength of the ship to take the rope is higher, and most of the existing tensile property detection devices are not provided with protection devices, so that dangerous situations are easy to occur when unqualified products are detected to cause rope breakage.

Disclosure of Invention

The invention aims to provide a tensile detection device for ship mooring ropes, which solves the problems that the strength of the ship mooring ropes is high, and most of the existing tensile detection devices are not provided with protection devices, so that dangerous situations are easy to occur when unqualified products are detected to generate rope breakage.

In order to achieve the above purpose, the present invention provides the following technical solutions: a tensile detection device for ship mooring ropes comprises a mounting base, a supporting frame, a lower clamping component, an upper clamping component and a moving table,

the mounting base comprises supporting feet, first universal wheels, first sliding grooves and first hydraulic rods, four supporting feet are arranged on the periphery of the bottom of the mounting base, four first sliding grooves are formed in the lower portion of the mounting base, and the first hydraulic rods are arranged in the first sliding grooves;

the support frame comprises a second chute, a second hydraulic rod, a third chute and first springs, two support frames are arranged, the support frames are respectively arranged on the left side and the right side of the top of the mounting base, the second chute is arranged above the right side of the left side of the support frame, the second hydraulic rod is arranged at the bottom of the second chute, the third chute is arranged below the right side of the left side of the support frame, and a plurality of first springs are arranged below the third chute;

the lower clamping assembly comprises a lower mounting frame, a tension sensor, a lower clamp, a second screw, a third screw and a connecting wire, wherein the lower clamping assembly is arranged above the mounting base, two sides of the lower mounting frame are respectively inserted into the left and right third sliding grooves, the lower clamp is arranged in the middle of the upper part of the lower mounting frame, and the tension sensor is arranged below the lower mounting frame;

the upper clamping assembly comprises a top frame, a telescopic rod, second springs, a buffer plate, an upper mounting frame and an upper clamp, the upper clamping assembly is arranged above the two support frames, the top frame is arranged at the top of the support frames, the buffer plate is arranged below the top frame through the telescopic rod, a plurality of second springs are arranged between the buffer plate and the top frame, the upper mounting frame is arranged below the buffer plate, and the upper clamp is fixedly arranged below the upper mounting frame;

the mobile station comprises a second universal wheel and a control assembly, the mobile station is arranged on the right side of the installation base, the control assembly is installed at the top of the mobile station, and the second universal wheel is installed at the bottom of the mobile station.

Preferably, a first universal wheel is mounted at the bottom of the first hydraulic rod.

Preferably, the second chute and the third chute of the support frame on the right side are symmetrical to the support frame on the left side.

Preferably, the top of the second hydraulic rod is in contact with the bottom of the upper mounting frame.

Preferably, the lower parts of the left side and the right side of the lower mounting frame are connected with the first springs.

Preferably, the lower fixture comprises a conical inner cavity, a sliding clamping block, a sliding block, a fourth sliding groove, a conical clamping block, a through hole, a rope binding groove, a limiting block and a first screw rod, the lower fixture is L-shaped, the lower fixture and the sliding clamping block form a complete cube, the conical inner cavity is formed in the middle of the tops of the lower fixture and the sliding clamping block, the sliding block is arranged at the bottom of the sliding clamping block, the fourth sliding groove is formed in the upper right side of the lower fixture, the conical clamping block is internally provided with the conical clamping block, the through hole is vertically formed in the middle of the conical clamping block, the rope binding groove is formed in the periphery of the conical clamping block, the limiting block is fixedly arranged at the front end of the lower fixture and the sliding clamping block, the first screw rod is arranged in the limiting block in a penetrating mode, and a fixing nut is arranged on the first screw rod.

Preferably, the upper part of the tension sensor is fixedly connected with the lower mounting frame through a second screw rod, the lower part of the tension sensor is fixedly connected with the mounting base through a third screw rod, and the tension sensor is connected with the control assembly through a connecting wire at the lower right side.

Preferably, the upper clamp and the lower clamp have the same structure.

Preferably, the control assembly is electrically connected with the first hydraulic rod, the second hydraulic rod and the tension sensor.

Compared with the prior art, the invention has the beneficial effects that: the tensile detection device of the ship mooring rope,

(1) Is provided with a buffer plate, the buffer plate is arranged below the top frame through a telescopic rod, a plurality of second springs are arranged between the buffer plate and the top frame, when the device breaks an unqualified rope, the upper mounting frame can continuously move upwards due to the action of inertia, the upper mounting frame is prevented from directly striking the top of the device under the action of the second spring, so that the shaking and tilting of the device are caused, personnel are prevented from being injured, and the safety of the device is further improved;

(2) The first spring is arranged, the lower mounting frame is fixedly connected with the mounting base through the tension sensor, but the impact can be caused to the lower mounting frame when the action force of the instantaneous burst of the detection rope is broken, and the impact can be relieved by the design of the first spring, so that the safety of the device is further improved;

(3) The lower clamp and the upper clamp are arranged, when the rope is fixed, the sliding clamping block is firstly slid rightwards, the conical clamping block is taken out, the lower end of the rope passes through the through hole from the upper part and is wound on the periphery of the conical clamping block, the conical clamping block is placed in the conical inner cavity, the sliding clamping block is closed, the upper end of the rope is clamped in the same mode, the first screw rod and the fixing nut are used for fixing the sliding clamping block and the lower clamp together, when the rope is pulled, the conical clamping block in the lower clamp moves upwards, the rope wound on the side face is clamped between the inner wall of the conical inner cavity and the rope binding groove, the rope is prevented from falling off when the rope is stretched, and the upper clamp is used for fixing the rope in the same mode, so that the fixing effect of the device is improved;

(4) The device comprises a first sliding groove, a first hydraulic rod and a second sliding groove, wherein the first sliding groove is arranged on the upper surface of the first sliding groove, the first sliding groove is provided with a supporting foot and a first universal wheel, the first hydraulic rod is arranged in the first sliding groove, when the device needs to move, the first hydraulic rod drives the first universal wheel to move downwards, the device is jacked up, the supporting foot is separated from the ground, and the device is moved through the first universal wheel, so that the convenience of the device in moving is improved;

(5) The second hydraulic rod is arranged, the top of the second hydraulic rod is in contact with the upper mounting frame, the upper mounting frame is driven to move upwards through the second hydraulic rod, the rope is driven to be pulled upwards, the clamping structure is prevented from being contacted with the driving structure by the pulling structure, damage to the driving structure caused by impact of the fixing structure in the moment of breaking the rope is prevented, and the service life of the device is prolonged.

Drawings

FIG. 1 is a schematic elevational view of the present invention;

FIG. 2 is an enlarged schematic view of the structure of the present invention at A;

FIG. 3 is a schematic cross-sectional view of the mounting base of the present invention;

FIG. 4 is a schematic cross-sectional view of a support frame according to the present invention;

FIG. 5 is a schematic cross-sectional view of the lower clamp of the present invention;

fig. 6 is a schematic perspective view of the lower fixture of the present invention.

In the figure: 1. mounting base, 101, supporting legs, 102, first universal wheels, 103, first sliding grooves, 104, first hydraulic rods, 2, supporting frames, 201, second sliding grooves, 202, second hydraulic rods, 203, third sliding grooves, 204, first springs, 3, lower clamping components, 301, lower mounting frames, 302, tension sensors, 303, lower clamps, 3031, conical inner cavities, 3032, sliding clamping blocks, 3033, sliding blocks, 3034, fourth sliding grooves, 3035, conical clamping blocks, 3036, through holes, 3037, rope-binding grooves, 3038, limiting blocks, 3039, first screws, 304, second screws, 305, third screws, 306, connecting wires, 4, upper clamping components, 401, top frames, 402, telescopic rods, 403, second springs, 404, buffer plates, 405, upper mounting frames, 406, upper clamps, 5, moving tables, 501, second universal wheels, 502 and control components.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-6, the present invention provides a technical solution: according to the tensile detection device of ship mooring ropes, according to the drawing, fig. 1, fig. 2 and fig. 3 show, install base 1 and include supporting legs 101, first universal wheel 102, first spout 103 and first hydraulic stem 104, install four supporting legs 101 all around the bottom of base 1, four first spouts 103 have been seted up to the below of installation base 1, first hydraulic stem 104 is all installed to inside first spout 103, first universal wheel 102 is installed to the bottom of first hydraulic stem 104, be convenient for drive the reciprocates of first universal wheel 102 through first hydraulic stem 104, support frame 2 includes second spout 201, second hydraulic stem 202, third spout 203 and first spring 204, support frame 2 is provided with two, support frame 2 installs the top left and right sides at installation base 1 respectively, second spout 201 has been seted up to the right side top of left side support frame 2, second spout 201's bottom is installed to the bottom, the top of second hydraulic stem 202 and the bottom contact of upper mounting bracket 405, be favorable to driving upper 405 through second hydraulic stem 202 and upwards moving, and then produce the third spout 203 and the inside of third support frame 203, the third spout 203 and the second support frame 2 are installed in the side of being convenient for slide position and the third support frame 203, the third spout 203 and the third support frame 2 are installed in the side of side 203.

According to the embodiment shown in fig. 4, 5 and 6, the lower clamping assembly 3 comprises a lower mounting frame 301, a tension sensor 302, a lower clamp 303, a second screw 304, a third screw 305 and a connecting wire 306, the lower clamping assembly 3 is arranged above the mounting base 1, two sides of the lower mounting frame 301 are respectively inserted into the left and right third sliding grooves 203, the lower sides of the lower mounting frame 301 are connected with the first springs 204, so as to buffer the impact received by the lower mounting frame 301, the lower clamp 303 is arranged in the middle of the upper part of the lower mounting frame 301, the lower clamp 303 comprises a conical inner cavity 3031, a sliding clamping block 3032, a sliding block 3033, a fourth sliding groove 3034, a conical clamping block 3035, a through hole 3036, a rope binding groove 3037, a limiting block 3038 and a first screw 3039, the lower clamp 303 is in an L shape, the lower clamp 303 and the sliding clamping block 3032 form a complete cube, the conical inner cavity 3031 is arranged in the middle of the top of the lower clamp 303 and the sliding clamping block 3032, the bottom of the sliding clamping block 3032 is provided with a sliding block 3033, the upper right side of the lower clamp 303 is provided with a fourth sliding groove 3034, the inside of the conical inner cavity 3031 is provided with a conical clamping block 3035, the middle part of the conical clamping block 3035 is vertically provided with a through hole 3036, the periphery of the conical clamping block 3035 is provided with a rope binding groove 3037, the front ends of the lower clamp 303 and the sliding clamping block 3032 are fixedly provided with a limiting block 3038, a first screw rod 3039 is arranged in the limiting block 3038 in a penetrating way, the first screw rod 3039 is provided with a fixing nut, the lower end of a rope is favorably fixed by the lower clamp 303, the lower side of the lower mounting bracket 301 is provided with a tension sensor 302, the upper side of the tension sensor 302 is fixedly connected with the lower mounting bracket 301 by a second screw rod 304, the lower side of the tension sensor 302 is fixedly connected with the mounting base 1 by a third screw rod 305, the tension sensor 302 is connected with the control component 502 by a connecting wire 306 at the lower right side, the pulling force that is convenient for detect rope through tension sensor 302 and receive goes up clamping assembly 4 and includes roof-rack 401, telescopic link 402, the second spring 403, buffer board 404, go up mounting bracket 405 and last anchor clamps 406, go up clamping assembly 4 and set up in two support frames 2 top, the roof-rack 401 is installed at support frame 2 top, the buffer board 404 is installed through telescopic link 402 to the below of roof-rack 401, install a plurality of second springs 403 between buffer board 404 and the roof-rack 401, the below of buffer board 404 is equipped with mounting bracket 405, the below fixed mounting of going up mounting bracket 405 has last anchor clamps 406, the structure of going up anchor clamps 406 and lower anchor clamps 303 is the same, be convenient for through the fixed of last anchor clamps 406 to the upper end of rope, mobile station 5 includes second universal wheel 501 and control assembly 502, mobile station 5 sets up on the right side at installation base 1, mobile station 5 top is installed control assembly 502, control assembly 502 and first hydraulic stem 104, second hydraulic stem 202, tension sensor 302 electric elements's start-stop in the control device is favorable to controlling means through control assembly 502, mobile station 5 bottom is installed second universal wheel 501.

Working principle: when the tensile detection device of the ship cable is used, the model of the tension sensor 302 is DYLY-103, firstly, the first hydraulic rod 104 in the first chute 103 is started through the control component 502, the first universal wheel 102 is ejected, then the device is moved to a designated position by the first universal wheel 102, the first hydraulic rod 104 is contracted to enable the supporting foot 101 to be contacted with the ground, then the sliding clamping block 3032 slides rightwards, the conical clamping block 3035 is taken out, the lower end of the rope passes through the through hole 3036 from above, the part through which the rope passes is wound in the peripheral rope-binding groove 3037 of the conical clamping block 3035, the conical clamping block 3035 is placed in the conical inner cavity 3031, the sliding clamping block 3032 is moved leftwards, the sliding clamping block 3032 is fixed with the lower clamp 303 by using the first screw 3039 and the fixed nut, the conical clamping block 3035 in the lower clamp 303 moves upwards when the rope is pulled, the rope wound on the side is clamped between the inner wall of the conical cavity 3031 and the rope binding groove 3037 to prevent the rope from falling off during stretching, meanwhile, the sliding block 3033 in the fourth sliding groove 3034 plays a role of preventing the sliding clamping block 3032 from falling off, the upper end of the rope is clamped in the upper clamp 406 in the same way, the second hydraulic rod 202 is started by the control component 502, the second hydraulic rod 202 drives the upper mounting frame 405 and the upper clamp 406 to move upwards to generate tension on the rope, the tension sensor 302 detects the tension and transmits data to the control component 502 through the connecting wire 306, the upper mounting frame 405 is contacted and separated with the second hydraulic rod 202 when the rope breaks, the upper mounting frame 405 moves upwards under the action of inertia and is contacted with the buffer plate 404, then the second spring 403 buffers the impact to avoid the danger caused by shaking of the device, the lower mounting frame 301 below is buffered by the first spring 204, to improve the safety of the device, what is not described in detail in this specification belongs to the prior art known to the person skilled in the art.

The terms "center," "longitudinal," "transverse," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used for descriptive simplicity and convenience only and not as an indication or implying that the apparatus or element being referred to must have a particular orientation, be constructed and operated for a particular orientation, based on the orientation or positional relationship illustrated in the drawings, and thus should not be construed as limiting the scope of the present invention.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims

1. The utility model provides a tensile detection device of boats and ships hawser, includes installation base (1), support frame (2), lower clamping assembly (3), goes up clamping assembly (4) and mobile station (5), its characterized in that:

the mounting base (1) comprises supporting feet (101), first universal wheels (102), first sliding grooves (103) and first hydraulic rods (104), four supporting feet (101) are arranged on the periphery of the bottom of the mounting base (1), four first sliding grooves (103) are formed in the lower portion of the mounting base (1), and the first hydraulic rods (104) are arranged in the first sliding grooves (103);

the support frame (2) comprises a second chute (201), a second hydraulic rod (202), a third chute (203) and first springs (204), wherein two support frames (2) are arranged, the support frames (2) are respectively arranged on the left side and the right side of the top of the installation base (1), the second chute (201) is arranged on the left side above the right side of the support frames (2), the second hydraulic rod (202) is arranged at the bottom of the second chute (201), the third chute (203) is arranged below the right side of the support frames (2), and a plurality of first springs (204) are arranged below the third chute (203);

the lower clamping assembly (3) comprises a lower mounting frame (301), a tension sensor (302), lower clamps (303), a second screw (304), a third screw (305) and a connecting wire (306), the lower clamping assembly (3) is arranged above the mounting base (1), two sides of the lower mounting frame (301) are respectively inserted into a left third sliding groove (203) and a right third sliding groove (203), the lower clamps (303) are arranged in the middle of the upper part of the lower mounting frame (301), the tension sensor (302) is arranged below the lower mounting frame (301), the lower sides of the lower mounting frame (301) are connected with the first springs (204), the lower clamps (303) comprise a conical inner cavity (3031), a sliding clamping block (3032), a sliding block (3033), a fourth sliding groove (3034), a conical inner cavity (3035), a through hole (3036), a rope groove (3037), a limiting block (3038) and a first screw (3039), the lower clamps (303) are L-shaped, the lower clamps (303) and the sliding clamping block (3032) are connected with the sliding block (3032), the sliding block (3032) and the sliding block (3033) is provided with the middle part of the sliding block (3032), a fourth chute (3034) is formed in the upper right side of the lower clamp (303), a conical clamping block (3035) is arranged in the conical inner cavity (3031), a through hole (3036) is vertically formed in the middle of the conical clamping block (3035), a rope binding groove (3037) is formed in the periphery of the conical clamping block (3035), limiting blocks (3038) are fixedly arranged at the front ends of the lower clamp (303) and the sliding clamping block (3032), a first screw rod (3039) is penetratingly arranged in each limiting block (3038), and a fixing nut is arranged on each first screw rod (3039);

the upper clamping assembly (4) comprises a top frame (401), a telescopic rod (402), a second spring (403), a buffer plate (404), an upper mounting frame (405) and an upper clamp (406), wherein the upper clamping assembly (4) is arranged above two supporting frames (2), the top frame (401) is arranged at the top of each supporting frame (2), the buffer plate (404) is arranged below the top frame (401) through the telescopic rod (402), a plurality of second springs (403) are arranged between the buffer plate (404) and the top frame (401), the upper mounting frame (405) is arranged below the buffer plate (404), and the upper clamp (406) is fixedly arranged below the upper mounting frame (405);

the mobile station (5) comprises a second universal wheel (501) and a control component (502), the mobile station (5) is arranged on the right side of the installation base (1), the control component (502) is installed at the top of the mobile station (5), and the second universal wheel (501) is installed at the bottom of the mobile station (5).

2. The ship cable tension detection device according to claim 1, wherein: the bottom of the first hydraulic rod (104) is provided with a first universal wheel (102).

3. The ship cable tension detection device according to claim 1, wherein: the positions of the second chute (201) and the third chute (203) of the support frame (2) on the right side are symmetrical to the support frame (2) on the left side.

4. The ship cable tension detection device according to claim 1, wherein: the top of the second hydraulic rod (202) is in contact with the bottom of the upper mounting frame (405).

5. The ship cable tension detection device according to claim 1, wherein: the upper side of the tension sensor (302) is fixedly connected with the lower mounting rack (301) through a second screw (304), the lower side of the tension sensor (302) is fixedly connected with the mounting base (1) through a third screw (305), and the tension sensor (302) is connected with the control assembly (502) through a connecting wire (306) at the lower right side.

6. The ship cable tension detection device according to claim 1, wherein: the upper clamp (406) and the lower clamp (303) have the same structure.

7. The ship cable tension detection device according to claim 1, wherein: the control component (502) is electrically connected with the first hydraulic rod (104), the second hydraulic rod (202) and the tension sensor (302).