CN116552756A - Cable release control device - Google Patents

Abstract

The invention discloses a cable release control device, which comprises: a frame body; the cable drum is rotatably connected to the frame body; damping device, arrange the one end at the support body, including: the damping mounting base body is assembled on the frame body; the hawser damping device is provided with 1 group at least, and it is including: the two damping installation bases are rotatably connected with each other, and each damping installation base is provided with a damping installation base; the first damping transmission device is linked with the cable damping device and can be driven to rotate when the cable accommodating piece rotates; the second damping transmission device is linked with the cable damping device so as to synchronize the 2 cable accommodating pieces; the locking braking piece is connected with the first damping transmission device; the locking and braking mechanism is arranged on the frame body and used for braking or unlocking the locking and braking piece. The cable release control device can prevent the cable from being embedded.

Description

Cable release control device

Technical Field

The invention belongs to the technical field of underwater equipment, and particularly relates to an improvement of a cable release control device structure.

Background

In many cases the equipment needs to be transported to the sea floor by means of a cable at a certain speed or some part of the equipment needs to be controlled at a desired depth, whereby a reliable cable release control is needed to do this;

some existing cable release control devices, such as winches, are arranged on a cable drum in a winding manner, when the cable is laid, the free end of the cable is connected with an anchor system, the anchor system pulls the cable drum to rotate to lower the cable under the action of gravity, when the anchor system is lowered under the condition of relatively high gravity, the acting force on the cable is relatively high, and the cable is embedded into the inner layer of the cable drum to generate a clamping phenomenon, so that the cable release control device cannot work normally.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a novel cable release control device which not only can accurately and firmly brake by a meshed transmission device during braking, but also can effectively solve the problem of cable embedding.

In order to achieve the aim of the invention, the invention is realized by adopting the following technical scheme:

a cable release control device comprising:

a frame body in which an accommodation space is formed;

the cable drum is positioned in the accommodating space, two ends of the cable drum are rotatably connected to the frame body, and a cable is wound on the cable drum;

damping device, arrange the one end of support body, it is including:

the damping mounting base body is assembled on the frame body;

the hawser damping device is provided with 1 group at least, and it is including:

the two cable accommodating parts are provided with 2 cable accommodating parts which are the same in size and are rotatably connected to the damping installation base body, and each cable accommodating part is provided with a cable accommodating part used for winding and arranging cables, so that the acting force transmitted to the cable drum can be reduced through friction force generated between the cable accommodating parts and the cables, and the cables are prevented from being embedded downwards;

the first damping transmission device is linked with the cable damping device and can be driven to rotate when the cable accommodating piece rotates;

the second damping transmission device is linked with the cable damping device so as to synchronize the 2 cable accommodating pieces;

the locking braking piece is connected with the first damping transmission device;

a lock braking mechanism arranged on the frame body and used for braking or unlocking the locking braking piece;

when the locking braking piece is locked or unlocked, the locking or unlocking of the first damping transmission device can be realized, and when the first damping transmission device is locked or unlocked by the damping locking piece, the cable accommodating piece can be locked or unlocked.

In some embodiments of the present application,

the cable accommodating part is a cable accommodating groove formed in the circumferential direction of the cable accommodating part, a plurality of cable accommodating grooves are formed in the cable accommodating part, the cable accommodating grooves are arranged in the axial direction of the cable accommodating part, and the cable is wound and arranged in 1 or more of the cable accommodating grooves.

In some embodiments of the present application,

the method also comprises the following steps:

the first installation shafts are provided with 2, are all connected to the damping installation base body in a rotating mode, and each first installation shaft is provided with the cable accommodating piece.

In some embodiments of the present application,

the first damping transmission device comprises:

the first damping assembly shaft is rotatably arranged on the damping installation base body;

the first damping driving piece is assembled on the first damping assembly shaft;

and the first damping driven piece is assembled on one of the first mounting shafts and is meshed and matched with the first damping driving piece.

In some embodiments of the present application,

the second damping transmission device is a damping chain wheel and chain structure and comprises:

damping chain wheels are provided with 2 damping chain wheels which are respectively assembled on 2 first mounting shafts;

damping chain, around setting up on 2 damping sprocket.

In some embodiments of the present application,

the damping mounting base body comprises damping mounting plates which are oppositely arranged, an accommodating space is formed between the 2 damping mounting plates, two ends of the first damping assembly shaft are respectively connected with the damping mounting plates in a rotating mode, the end portions of the first damping assembly shaft extend out of the damping mounting plates, and the locking braking piece is assembled on the first damping assembly shaft.

In some embodiments of the present application,

the lock stop actuating mechanism comprises:

a locking body member circumferentially disposed about the locking detent member, said locking body member partially disposed against said locking detent member to provide a damping force to said locking detent member, one end of which is hinged to said damping mount base;

a locking drive member having a retractable extension;

the locking linkage piece is rotatably arranged on the damping installation base body, one end of the locking linkage piece is hinged with the extending part, and the other end of the locking linkage piece is hinged with the other end of the locking body piece, so that the locking body piece can be driven by the locking driving piece to act so as to drive the locking body piece to act, and the locking body piece is propped against the locking braking piece to lock the first damping transmission device or separate from the first damping transmission device to unlock the first damping transmission device.

In some embodiments of the present application,

an annular accommodating part is formed on the locking braking piece;

the locking body spare is semi-annular, has the opening, including:

the body part is positioned in the accommodating part and is at least partially fit with the accommodating part;

and the first connecting part and the second connecting part are arranged at two sides of the opening and are respectively connected with two ends of the body part, and the first connecting part and the second connecting part are gradually far away from the locking braking part compared with the body part.

In some embodiments of the present application,

be provided with the cable locating part of transverse arrangement at 2 damping mounting panel connections on the damping mounting base member, the cable locating part is provided with a plurality ofly, arranges along damping mounting panel circumference.

In some embodiments of the present application, the frame body includes:

the frame body supports the end covers, which are provided with 2, and are oppositely arranged;

the connecting protection rods are connected between the 2 frame body supporting end covers and are arranged along the circumferential direction of the frame body supporting end covers;

wherein, be formed with between support body support end cover and connection protection pole accommodation space.

Other features and advantages of the present invention will become apparent upon review of the detailed description of the invention in conjunction with the drawings.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of a cable release control device in accordance with an embodiment of the present invention;

FIG. 2 is a schematic view of a damping device of a cable release control device according to an embodiment of the present invention;

FIG. 3 is a schematic view of the combination of a damping device and a locking brake mechanism of a cable release control device according to an embodiment of the present invention;

FIG. 4 is a force analysis chart of a cable release control device in accordance with an embodiment of the present invention.

Description of the embodiments

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the accompanying drawings and examples.

It should be noted that, in the description of the present invention, terms such as "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate directions or positional relationships based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the apparatus or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus are not to be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The invention provides an embodiment of a cable release control device, which comprises:

a frame 110, a damping device 200, a braking device 400, a cable clamping device 300, a cable guide device 600 and a self-locking device 500 arranged on the frame 110. The underwater positioning and releasing device is mainly matched with the anchor device to carry out underwater deployment operation, so that equipment carried by the device can be kept in a certain depth range, and accurate fixed-depth release is realized.

In some embodiments of the present application, the frame 110 includes:

the number of the frame body support end covers 111 is 2, the frame body support end covers 111 are arranged oppositely, and the frame body support end covers 111 are round end covers;

and connection protection rods 112 connected between the 2 frame body support end covers 111, the connection protection rods 112 being provided in plurality and arranged along the circumferential direction of the frame body support end covers 111;

wherein the receiving space is formed between the frame body supporting end cover 111 and the connection preventing lever 112.

The support framework of the whole underwater fixed-depth release device is formed by the support end cover 111 of the frame body and a plurality of connecting protection rods 112.

In order to achieve the purpose of weight reduction, the support end cover 111 of the frame body is further provided with a plurality of weight reducing holes, which can be uniformly arranged on the support end cover 111 of the frame body.

A cable drum 120 for winding and disposing a cable having a length extending from one of the frame support end caps 111 to a position of the other frame support end cap 111.

The end projections form spool shafts that are rotatably coupled to the housing support end caps 111 to provide rotational coupling of the cable drum 120 relative to the housing support end caps 111.

The end cap 111 is supported by the cable drum 120 against the frame body for continuous release of the cable as the cable is being unwound.

To achieve a limit on the winding length of the cable wound on the cable drum 120, a rotation limiting disc is provided at least one end of the cable drum 120, which is integrally fixed with the cable drum 120.

The damping device 200 is disposed at one end of the frame 110, and in particular, the damping device 200 is mounted on the frame support end cover 111 at one end thereof.

The damping device 200 comprises:

a damping mount base 210 mounted on the frame 110;

the cable damper 220 is provided with at least 1 group, and comprises:

the cable receiving members 221 are provided in 2 numbers, which are different in size, and are rotatably coupled to the damping mount base 210.

In some embodiments of the present application, to achieve the rotational connection of the cable receiving members 221, there are provided first mounting shafts 230, 2, each rotatably connected to the damping mounting base 210, and each of the first mounting shafts 230 is provided with the cable receiving member 221.

A cable receiving part 222 for winding and arranging the cable is formed on each of the cable receiving parts 221, which can reduce the force transferred to the cable drum 120 by generating friction with the cable to prevent the cable from being embedded;

the cable accommodating part 222 is a cable accommodating groove formed along the circumferential direction of the cable accommodating piece 221, a plurality of cable accommodating grooves are formed, the cable accommodating groove is arranged along the axial direction of the cable accommodating piece 221, and the cable is wound and arranged in 1 or more cable accommodating grooves.

The cable accommodating member 221 is a cable accommodating wheel, and a plurality of cable accommodating grooves are formed above the cable accommodating wheel.

Winding the cable in the cable receiving slot can be used for increasing the damping force between the cable and the cable receiving slot;

the more windings, the greater the contact area of the cable with the cable receiving member 221 and the greater the damping friction it generates. The cable receiving member 221 is wound several times depending on the required damping strength, and is wound more and less if required.

Of course, in order to ensure that the cable can be moved downwards to be pulled when passing through the cable accommodating part 221, the friction damping force between the cable and the cable accommodating part 221 is not easily excessive so as not to influence the normal cable discharging;

the diameters of the 2 cable accommodating wheels are set to be the same.

The first damping transmission device 240 is linked with the cable damping device 220 and can be driven to rotate when the cable accommodating piece 221 rotates;

in some embodiments of the present application, the first damping transmission 240 includes:

a first damper assembly shaft 241 rotatably mounted on the damper mounting base 210;

a first damping driving part 242 mounted on the first damping mounting shaft 241;

a first damping follower 243 is mounted on one of the first mounting shafts 230 for meshing engagement with the first damping driving member 242.

In some embodiments of the present application, the first damping drive 242 is a first drive damping gear;

the first damping follower 243 is a first driven damping gear, and the first damping follower and the first driven damping gear are engaged.

The cable on the cable drum 120 is wound and unwound under the gravity traction of the anchor device, and the opened cable passes through the cable accommodating part 221, so that the cable accommodating part 221 is driven to rotate relative to the damping mounting base 210 due to friction force between the cable accommodating part 221 and the cable, the cable accommodating part 221 rotates to drive the first mounting shaft 230 to rotate, and then the first damping driven part 243 on the first mounting shaft 230 is driven to rotate, and the first damping driven part 243 is meshed with the first damping driving part 242 to drive the first damping rotating part to rotate.

Due to the linkage of the first damping actuator 240 and the cable receiving member 221, the damping effect between the cable receiving member 221 and the cable is enhanced by the provision of the first damping device 200.

A second damping actuator 250, which is coupled to the cable damping device 220 to synchronize the 2 cable containers 221;

in some embodiments of the present application,

the second damping transmission device 250 is a damping sprocket 251 chain structure, and includes:

the damper sprockets 251, provided in 2, respectively fitted on the 2 first mounting shafts 230;

the damper chain 252 is wound around 2 damper sprockets 251.

The two groups of cable winding wheels of the damping system are externally provided with synchronous chains, 2 damping chain wheels 251 are connected together through the damping chains 252, and as the 2 damping chain wheels 251 are respectively assembled on the first installation shaft 230 and are coaxially arranged with 2 cable accommodating pieces 221, the 2 cable accommodating pieces 221 connected with the damping chain wheels 251 are driven by the damping chains 252 to realize synchronous rotation, and the aim of ensuring synchronous actions of the two cable accommodating pieces 221 is that: preventing one of the cable receiving members 221 from slipping or failing due to insufficient friction, preventing damping from being reduced due to slipping or failing, and ensuring damping effect.

Without the cable receiving member 221 of the present embodiment, the weight of the anchor device would create a downward pulling force on the cable when the anchor device is suspended from the cable end, which would be transmitted to the cable at the cable drum 120, resulting in the cable being embedded in the inner layer of the multi-layered cable on the cable drum 120 due to the high force.

In this embodiment, the cables led out from the cable drum 120 are sequentially wound and arranged in the cable accommodating grooves of the cable accommodating member 221, when the cables are wound in the cable accommodating grooves, friction force is generated between the cables and the cable accommodating grooves, and the force reducing effect on the force borne by the cables can be realized through the friction force between the cables and the cable accommodating grooves;

after the pulling force of the cable passes through the multi-stage friction of the 2 cable receivers 221, the force thereon is reduced to a reasonable level.

And further, the acting force on the cable is reduced when the acting force is transmitted to the cable drum 120, so that the problem that the cable at the cable drum 120 is embedded into the inner layer due to the fact that the acting force is transmitted to the cable drum 120 is effectively avoided.

The cable is wound on the cable accommodating part 221, the total wrap angle of the cable on the cable accommodating part 221 is set as a, the downward pulling force of the connecting section of the cable and the anchor device, namely the stress of the traction end is F1, the stress of the cable drum leading to the cable storage winch is F2, F is the friction force between the cable and the cable accommodating part 221, the cable with a small wrap angle da is taken for stress analysis, and the difference of the tension of the cables at two ends can be obtained through balance conditions, namely the friction force, and F1-F2=f. When da is infinity, dN is the pressure applied to the cable in the direction along the diameter of the wheel.

The greater the friction between the cable and the cable receiving member, the more pronounced the force reducing effect.

A locking brake coupled to the first dampened transmission 240;

a locking stopper mechanism 270 disposed on the frame 110 for braking or unlocking the locking stopper;

the locking or unlocking of the first damping transmission device 240 can be realized when the locking braking member is locked or unlocked, and the cable accommodating member 221 can be locked or unlocked when the first damping transmission device 240 is locked or unlocked by the damping locking member.

In some embodiments of the present application,

the damping mounting base 210 includes damping mounting plates 211 disposed opposite to each other, an accommodating space is formed between the 2 damping mounting plates 211, two ends of the first damping mounting shaft 241 are respectively rotatably connected to the damping mounting plates 211, ends of the first damping mounting shaft 241 extend from the damping mounting plates 211, and the locking brake is mounted on the first damping mounting shaft 241.

When the locking braking member is locked, the locking mechanism 270 can be controlled to act so as to lock the locking braking member, and as the locking braking member is connected with the first damping assembly shaft 241 of the first damping transmission device 240, when the locking braking member is locked, the corresponding first damping assembly shaft 241 is driven to not rotate any more, so that the first damping driving member 242 and the first damping driven member 243 assembled above the locking braking member are driven to be engaged and locked together, and the cable accommodating member 221 connected with the first damping driven member 243 and the other cable accommodating member 221 linked with the first damping driving member are driven to be locked and fixed.

When the locking mechanism 270 is actuated, the first damping follower 243 and the first damping driver 242 can be engaged and locked together by the teeth of each other, so that the rotation of the cable receiving member 221 and the cable is effectively avoided.

In some embodiments of the present application, the lock stop mechanism 270 includes:

a locking body member 271 circumferentially arranged around the locking stopper member, one end of which is hinged to the damper mounting base 210, the locking body member 271 being partially disposed against the locking stopper member to provide a damping force to the locking stopper member;

a lock drive 272 having a telescopic extension;

the locking driving member 272 is a locking driving cylinder, and the extension portion is a locking extension arm, which can be used for telescopic motion.

The locking linkage member 273 is rotatably mounted on the damping mounting base 210, one end of the locking linkage member is hinged to the protruding portion, and the other end of the locking linkage member is hinged to the other end of the locking body member 271, so that the locking body member 271 can be driven by the locking driving member 272 to act so as to enable the locking body member 271 to abut against the locking braking member to lock the first damping transmission device 240 or disengage from the first damping transmission device 240 to unlock the first damping transmission device 240.

The lock link 273 is a lock lever that is rotatably connected to the damper mounting plate 211 by a connecting pin.

A fitting rod is formed at an end of the lock link member 273, a fitting hole is formed on the lock body member 271, and the lock link member 273 is fitted into the fitting hole by the fitting rod to achieve rotational connection with the lock body member 271.

In some embodiments of the present application,

an annular accommodating portion 261 is formed on the locking brake;

the locking body member 271 is semi-annular, has an opening, and includes:

a body portion located within the receiving portion and at least partially in snug fit with the annular receiving portion 261;

and a first connecting portion 2711 and a second connecting portion 2712 disposed on both sides of the opening and connected to both ends of the body portion, respectively, the first connecting portion 2711 and the second connecting portion 2712 being gradually distant from the locking stopper than the body portion.

When the lock driving member 272 and the lock link member 273 are not operated, the first and second connection portions 2711 and 2712 remain with a gradual distance from the lock brake member so that the lock body member 271 partially remains in contact with the lock brake member.

When braking is needed, the first connecting part 2711 and the second connecting part 2712 at the two ends can be driven to be contacted and abutted with the locking braking piece, so that the braking effect is realized.

In some embodiments of the present application,

the damping mounting base 210 is provided with a plurality of cable stoppers 280 which are transversely arranged on the damping mounting plates 211 and connected with each other, and the cable stoppers 280 are circumferentially arranged along the damping mounting plates 211.

The cable limiting member 280 is a cable limiting rod, and is provided with a plurality of cable limiting rods, so as to prevent cables arranged in the damping mounting plate 211 from playing a role of limiting and falling off.

The cable release control device in the embodiment not only can prevent the cable from being embedded downwards, but also can realize braking and braking of the cable, and the braking and braking are realized through the meshed gear piece in a braking and braking mode, so that the braking effect is good, and the braking precision is high.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be apparent to one skilled in the art that modifications may be made to the technical solutions described in the foregoing embodiments, or equivalents may be substituted for some of the technical features thereof; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (10)

1. A cable release control device comprising:

a frame body in which an accommodation space is formed;

the cable drum is positioned in the accommodating space, two ends of the cable drum are rotatably connected to the frame body, and a cable is wound on the cable drum;

damping device, arrange the one end of support body, it is including:

the damping mounting base body is assembled on the frame body;

the hawser damping device is provided with 1 group at least, and it is including:

the two cable accommodating parts are provided with 2 cable accommodating parts which are the same in size and are rotatably connected to the damping installation base body, and each cable accommodating part is provided with a cable accommodating part used for winding and arranging cables, so that the acting force transmitted to the cable drum can be reduced through friction force generated between the cable accommodating parts and the cables, and the cables are prevented from being embedded downwards;

the first damping transmission device is linked with the cable damping device and can be driven to rotate when the cable accommodating piece rotates;

the second damping transmission device is linked with the cable damping device so as to synchronize the 2 cable accommodating pieces;

the locking braking piece is connected with the first damping transmission device;

a lock braking mechanism arranged on the frame body and used for braking or unlocking the locking braking piece;

when the locking braking piece is locked or unlocked, the locking or unlocking of the first damping transmission device can be realized, and when the first damping transmission device is locked or unlocked by the damping locking piece, the cable accommodating piece can be locked or unlocked.

2. The cable release control device of claim 1, wherein,

the cable accommodating part is a cable accommodating groove formed in the circumferential direction of the cable accommodating part, a plurality of cable accommodating grooves are formed in the cable accommodating part, the cable accommodating grooves are arranged in the axial direction of the cable accommodating part, and the cable is wound and arranged in 1 or more of the cable accommodating grooves.

3. The cable release control device of claim 1, wherein,

the method also comprises the following steps:

the first installation shafts are provided with 2, are all connected to the damping installation base body in a rotating mode, and each first installation shaft is provided with the cable accommodating piece.

4. The cable release control device of claim 1, wherein,

the first damping transmission device comprises:

the first damping assembly shaft is rotatably arranged on the damping installation base body;

the first damping driving piece is assembled on the first damping assembly shaft;

and the first damping driven piece is assembled on one of the first mounting shafts and is meshed and matched with the first damping driving piece.

5. The cable release control device of claim 4, wherein,

the second damping transmission device is a damping chain wheel and chain structure and comprises:

damping chain wheels are provided with 2 damping chain wheels which are respectively assembled on 2 first mounting shafts;

damping chain, around setting up on 2 damping sprocket.

6. The cable release control device of claim 5, wherein,

the damping mounting base body comprises damping mounting plates which are oppositely arranged, an accommodating space is formed between the 2 damping mounting plates, two ends of the first damping assembly shaft are respectively connected with the damping mounting plates in a rotating mode, the end portions of the first damping assembly shaft extend out of the damping mounting plates, and the locking braking piece is assembled on the first damping assembly shaft.

7. The cable release control device of claim 1, wherein,

the lock stop actuating mechanism comprises:

a locking body member circumferentially disposed about the locking detent member, said locking body member partially disposed against said locking detent member to provide a damping force to said locking detent member, one end of which is hinged to said damping mount base;

a locking drive member having a retractable extension;

the locking linkage piece is rotatably arranged on the damping installation base body, one end of the locking linkage piece is hinged with the extending part, and the other end of the locking linkage piece is hinged with the other end of the locking body piece, so that the locking body piece can be driven by the locking driving piece to act so as to drive the locking body piece to act, and the locking body piece is propped against the locking braking piece to lock the first damping transmission device or separate from the first damping transmission device to unlock the first damping transmission device.

8. The cable release control device of claim 7, wherein,

an annular accommodating part is formed on the locking braking piece;

the locking body spare is semi-annular, has the opening, including:

the body part is positioned in the accommodating part and is at least partially fit with the accommodating part;

and the first connecting part and the second connecting part are arranged at two sides of the opening and are respectively connected with two ends of the body part, and the first connecting part and the second connecting part are gradually far away from the locking braking part compared with the body part.

9. The cable release control device of claim 6, wherein a plurality of cable retainers are provided on the damper mounting base and are disposed transversely to the damper mounting plates, the cable retainers being disposed circumferentially along the damper mounting plates.

10. The cable release control device of claim 1, wherein the frame comprises:

the frame body supports the end covers, which are provided with 2, and are oppositely arranged;

the connecting protection rods are connected between the 2 frame body supporting end covers and are arranged along the circumferential direction of the frame body supporting end covers;

wherein, be formed with between support body support end cover and connection protection pole accommodation space.