Patent Description:
With development and application of new energy, the application of a floating wind power system has become an inevitable trend to obtain high-quality wind resources and reduce construction costs. At present, the floating wind power system is mainly used in shallow waters with water depth less than <NUM>. The floating wind power system includes floating fan, dynamic cable and static cable, where one end of the dynamic cable is connected with the floating fan and the other end thereof is connected with the static cable, that is, the power generated by the floating fan can be transmitted through the dynamic cable and the static cable.

At present, line shape of the dynamic cable is mainly formed by a buoyancy block or a clump weight pressing the dynamic cable into "S" or "W" shape. The "S" or "W" shape can meet drift of the floating fan in a large range, and relieve axial tension of the dynamic cable during drift of the floating fan. Specifically, both the buoyancy block and the clump weight need to be fixed to the dynamic cable, with the buoyancy block applying upward buoyancy to the dynamic cable, and the clump weight applying downward pressure to the dynamic cable, so as to set the line shape of the dynamic cable to a preset shape.

However, when a sea condition is severe, the dynamic cable will drift in a wide range under action of waves and currents. After drifting in a wide range, the dynamic cable is easy to collide with the floating fan or an anchor chain of the floating fan and then fail. Document <CIT> is a prior art example of a dynamic cable applied on a floating wind turbine.

Embodiments of the present application provide a shallow water floating wind power system and a dynamic cable assembly thereof to solve the problem that when the sea condition is severe, the existing dynamic cable drifts in a wide range under the action of waves and currents, and the dynamic cable after drifting in a wide range of drift is prone to collide with the floating fan or the anchor chain of the floating fan and thus resulting in failure.

According to the present invention, there is provided a dynamic cable assembly for a shallow water floating wind power system, including:.

In an optional implementation mode, the elastic cable includes a first connecting plate, a second connecting plate and a spring, the first connecting plate is parallel to the second connecting plate, the first connecting plate is provided above the second connecting plate, one end of the spring is fixed to the first connecting plate, and the other end of the spring is fixed to the second connecting plate; a through hole is provided in middle of the first connecting plate, a part of the mooring chain near the bottom end thereof is provided to pass through the through hole of the first connecting plate and is fixedly connected to the first connecting plate. Those skilled in the art can understand that when an impact on the dynamic cable is too large, the elastic cable may play a buffering role through extension of the spring to avoid damage to the dynamic cable at a position where the dynamic cable is connected with the mooring chain due to excessive impact.

In an optional implementation mode, the connection unit further includes a monitoring component and an anchor, the monitoring component is provided with a wireless communication module, a main body of the monitoring component is fixedly connected to the dynamic cable, and the mooring chain is a power transmission line of the monitoring component;
the anchor is fixedly connected with the seabed, and the second connecting plate is installed at top of the anchor, a middle part of the second connecting plate is provided with a through hole in middle thereof, the anchor is internally provided with a power supply, and a bottom end of the power transmission line passes through the through hole of the second connecting plate and is connected with the power supply in the interior of the anchor. Those skilled in the art can understand that the monitoring component may monitor the force and movement state of the dynamic cable at a position where the dynamic cable is connected with the mooring chain, and when the force and the displacement at the position exceed a preset value, the monitoring component sends an alarm signal to a remote device through the wireless communication module.

In an optional implementation mode, a part of the power transmission line between the first connecting plate and the second connecting plate has a length greater than maximum length to which the spring is stretched. Those skilled in the art can understand that through the above setting may ensures that the power transmission line will not be pulled and broken when the spring is stretched.

In an optional implementation mode, the main body of the monitoring component is connected with the dynamic cable through a bend limiting caliper, the bend limiting caliper includes a clamping section and cone sections provided on both sides of the clamping section, the cone section is made of an elastic material and a large diameter end of the cone section is fixedly connected with the clamping section; the dynamic cable is provided to pass inside the two cone sections, and the clamping section is fastened to a part of the dynamic cable between the two cone sections; the main body of the monitoring component is fastened to the clamping section. Those skilled in the art can understand that through the provision of the bend limiting caliper, the bend limiting caliper can limit a bending radius of the dynamic cable, avoiding rupture of outer sheath of the dynamic cable and failure of functional units of the dynamic cable due to stress concentration caused by excessive bending of the dynamic cable; and the bend limiting caliper may also increase fatigue resistance of the dynamic cable and improve service life of the dynamic cable.

In an optional implementation mode, the buoyancy unit includes a plurality of buoyancy blocks, the buoyancy blocks are fastened to the dynamic cable, and the plurality of buoyancy blocks are provided at intervals along an extension direction of the dynamic cable. Those skilled in the art can understand that through providing a plurality of buoyancy blocks, net buoyancy of the buoyancy unit may be increased, thus improving load-bearing capacity of the dynamic cable, and thus shellfish, algae and other organisms attached to the dynamic cable in shallow water are not easy to lower the line shape of the dynamic cable, reducing a risk of scraping between the dynamic cable and the seabed.

In an optional implementation mode, a distance between two adjacent buoyancy blocks in the buoyancy unit is <NUM>-<NUM> times the length of the buoyancy blocks. Those skilled in the art can understand that through the above setting, excessive bending can be prevented in an area of the dynamic cable between two buoyancy blocks, thereby ensuring transmission stability of the dynamic cable.

In an optional implementation mode, the dynamic cable assembly further includes a bend limiting cylinder, the bend limiting cylinder is made of an elastic material, the bend limiting cylinder is formed into a conical structure, a large diameter end of the conical structure is provided with a plurality of bolts for fastening connection with the floating fan, and the first end of the dynamic cable is provided to pass inside the conical structure and is fixedly connected with the floating fan. Those skilled in the art can understand that through the provision of the bend limiting cylinder, the first end of the dynamic cable can be prevented from excessive bending and the transmission stability of the dynamic cable can be guaranteed.

In an optional implementation mode, the dynamic cable assembly further includes a clump weight fastened to the dynamic cable, and the clump weight is installed in the first valley section. Those skilled in the art can understand that through the provision of the clump weight at a side of the first valley section facing the floating fan, the clump weight applies downward gravity to the dynamic cable, which, on the one hand, enables the dynamic cable to form the first valley section, and on the other hand, may prevent the dynamic cable from floating above sea surface.

According to another aspect of the present invention, there is provided a shallow water floating wind power system, including a floating fan, a static cable and the above-mentioned dynamic cable assembly;
the floating fan floats on sea surface, the static cable is fixed to the seabed, and one end of the dynamic cable in the dynamic cable assembly is connected with the floating fan, and the other end of the dynamic cable is connected with the static cable.

Those skilled in the art can understand that in the dynamic cable assembly for a shallow water floating wind power system according to the present application, the dynamic cable is used to connect the floating fan and the static cable, and the buoyancy unit and connection unit are both connected with the dynamic cable, the connection unit and the buoyancy unit jointly define the line shape of the dynamic cable, the line shape of the dynamic cable includes the first valley section, the peak section and the second valley section, the buoyancy unit is provided at the top of the peak section, and the connection unit is located at the side of the peak section away from the floating fan. In this way, the dynamic cable can meet a drift requirement of the floating fan through the deformation of the first valley section, the peak section and the second valley section. The side of the peak section far away from the floating fan is connected with the seabed through the connection unit, and when the sea condition is severe, the connection unit will play a limiting role on the dynamic cable, to avoid collision and failure of the dynamic cable due to a wide range of drift. In addition, since there is provided the elastic cable between the mooring chain of the connection unit and the seabed, when the impact borne by the dynamic cable is too large, the connection unit can play a buffering role by elastic deformation of the elastic cable, reducing the impact load on the dynamic cable, and avoiding the damage at the position where the dynamic cable is connected with the mooring chain due to excessive impact.

The In order to more clearly explain technical solutions in embodiments of the present application or in prior art, the following will briefly introduce drawings used in descriptions of the embodiments or prior art. It is obvious that the drawings in the following description are some embodiments of the present application, and for those skilled in the art, other drawings can be obtained from these drawings without any creative work.

First of all, those skilled in the art should understand that these embodiments are only used to explain technical principles of the present application and are not intended to limit the scope of protection of the present application. Those skilled in the art may adjust them as needed so as to adapt to specific applications.

Secondly, it should be noted that in description of the present application, terms indicating direction or position relationship, such as "inside", "outside" and the like, are based on the direction or position relationship shown in accompanying drawings, and is only for the convenience of description, not to indicate or imply that the device or the component must have a specific orientation, or be constructed and operated in a specific orientation, so those terms cannot be understood as a limitation of the present application.

At present, near-shore water depth of our country's sea area changes little, and the water depth generally does not exceed <NUM>. Meanwhile, environment of a sea area where a floating fan is located is usually very severe, and the floating fan will have a very large drift under loads applied by winds, waves and currents. A dynamic cable is mainly pressed into "S" or "W" shape by the buoyancy block or the clump weight. The line shape "S" or "W" ensures that the dynamic cable can meet a wide range of drift of the floating fan, and relieve axial tension of the dynamic cable during the drift of the floating fan. Specifically, both the buoyancy block and the clump weight need to be fixed to the dynamic cable, the buoyancy block applies upward buoyancy to the dynamic cable, and the clump weight applies downward pressure to the dynamic cable, so as to set a line shape of the dynamic cable to a preset shape. However, in order to ensure that the shallow water floating wind power system can generate electricity uninterruptedly, the dynamic cable must have a high degree of integrity, that is, structure of the dynamic cable cannot be damaged. When the sea condition is severe, the dynamic cable will drift in a wide range under actions of waves and currents. After the dynamic cable drifts in a wide range, on the one hand, the dynamic cable is easy to be pulled and broken in the water, and on the other hand, the dynamic cable is easy to collide with the floating fan or an anchor chain of the floating fan, and then becomes failed.

After repeated thinking and verification, the applicant found that if a part of the dynamic cable can be connected with a seabed via a connection unit, and the connection unit is provided with an elastic cable, then impact load of the dynamic cable under impact of waves and currents can be reduced through elastic deformation of the elastic cable, and the connection unit and a buoyancy unit jointly define a line shape of the dynamic cable. Where the line shape of the dynamic cable includes a first valley section connected with the floating fan, multiple peak sections connected with the first valley section, and a second valley section between two adjacent peak sections. In this way, when the floating fan drifts, the dynamic cable can meet the drift of the floating fan through deformation of the first valley section and the peak sections, and when the floating fan drifts, the deformation of the first valley section and the peak sections can relieve the axial tension of the dynamic cable. In addition, when the sea condition is severe, the connection unit can prevent the dynamic cable itself from drifting in a wide range, and avoid the dynamic cable to be collided with the floating fan or the anchor chain of the floating fan and failure.

In view of this, the applicant designed a dynamic cable assembly for the shallow water floating wind power system, including: a dynamic cable, a plurality of buoyancy units and a plurality of connection units. Where the dynamic cable is used to connect the floating fan and a static cable, and the connection units connect the dynamic cable to a seabed through an elastic cable and a mooring chain. The buoyancy units and the connection units define a line shape of the dynamic cable, the line shape of the dynamic cable includes a first valley section connected with the floating fan, a plurality of peak sections connected with the first valley section and a second valley section between adjacent two peak sections. Each buoyancy unit is correspondingly provided at top of one peak section, and each connection unit is correspondingly provided at a side of one peak section away from the floating fan. In this way, the dynamic cable can meet the drift requirement of the floating fan in a wide range. When the sea condition is severe, the connection unit can prevent the dynamic cable from drifting in a wide range and colliding with the floating fan or the anchor chain of the floating fan, resulting in failure, and furthermore, the elastic cables of the connection units can play a role in absorbing impact load to avoid the dynamic cable from being damaged due to excessive impact.

<FIG> is a schematic structural diagram of a shallow water power generation system provided by an embodiment of the present application; <FIG> is a partial enlarged schematic diagram at A in <FIG>; <FIG> is a schematic structural diagram of an elastic cable provided by an embodiment of the present application; <FIG> is a schematic structural diagram of another shallow water power generation system provided by an embodiment of the present application; <FIG> is a schematic structural diagram of a buoyancy block provided by an embodiment of the present application; <FIG> is a left view of the buoyancy block in <FIG>; <FIG> is a schematic structural diagram of a bend limiting caliper provided by an embodiment of the present application; <FIG> is a left view of the bend limiting caliper in <FIG>; <FIG> is a schematic structural diagram of a bend limiting cylinder provided by an embodiment of the present application; <FIG> is a left view of the bend limiting cylinder in <FIG>; <FIG> is a schematic structural diagram of a clump weight provided by an embodiment of the present application; <FIG> is a left view of the clump weight in <FIG>.

As shown in <FIG>, a dynamic cable assembly for a shallow water floating wind power system provided by this embodiment includes a dynamic cable <NUM>, a plurality of buoyancy units and a plurality of connection units <NUM>, where a first end of the dynamic cable <NUM> is used to connect a floating fan <NUM>, and a second end of the dynamic cable <NUM> is used to connect a static cable. <FIG> shows that a left end of the dynamic cable <NUM> is electrically connected to the floating fan <NUM>, and a right end of the dynamic cable <NUM> is used to connect the static cable such as a power cable or a static array formed by a plurality of static cables. It is easy to understand that the dynamic cable <NUM> can be used to transmit power and/or communication control signals. Those skilled in the art can set a specific structure of the dynamic cable <NUM> according to a specific type of signals transmitted by the dynamic cable <NUM>. This embodiment here does not limit the specific structure of the dynamic cable <NUM>.

As shown in <FIG>, the plurality of buoyancy units are provided on the dynamic cable <NUM> at intervals. It is easy to understand that density of the buoyancy units is less than density of sea water. The buoyancy units provided on the dynamic cable <NUM> can provide upward buoyancy for the dynamic cable <NUM>. The connection unit <NUM> includes a mooring chain <NUM> and an elastic cable <NUM>, a bottom end of the elastic cable <NUM> is fixedly connected with a seabed <NUM>, a top end of the elastic cable <NUM> is fixedly connected with the mooring chain <NUM> at a position near a bottom end of the mooring chain <NUM>, and a top end of the mooring chain <NUM> is fixedly connected with the dynamic cable <NUM>. It is easy to understand that the elastic cable <NUM> can undergo elastic deformation when subjected to tension, thus the elastic cable will be extended in length. After the tension disappears, the length of the elastic cable <NUM> will return to its initial state. By providing the connection unit <NUM>, the mooring chain <NUM> and the elastic cable <NUM> of the connection unit <NUM> can limit the dynamic cable <NUM>, that is, limit maximum distance between the dynamic cable <NUM> connects and the seabed <NUM> at a position where the dynamic cable <NUM> is connected with the mooring chain <NUM>. In addition, the mooring chain <NUM> and the elastic cable <NUM> can also prevent the dynamic cable <NUM> from rising to sea surface <NUM> under the buoyancy of the buoyancy unit.

Continuing to refer to <FIG>, the connection unit <NUM> and the buoyancy unit jointly define the line shape of the dynamic cable <NUM>. The line shape of the dynamic cable <NUM> includes a first valley section <NUM> connected to the floating fan <NUM>, a plurality of peak sections <NUM> connected to the first valley section <NUM>, and a second valley section <NUM> between two adjacent peak sections <NUM>. Exemplarily, a length of the peak section <NUM> may be <NUM>-<NUM> times the depth of water. It is worth mentioning that a height of a top end of the peak section <NUM> is less than a height of the sea surface <NUM>, so as to avoid aging of an outer sheath of the dynamic cable <NUM> due to direct sunlight onto the dynamic cable <NUM> and ensure service life of the dynamic cable <NUM>. It is easy to understand that number of the peak sections <NUM> is not limited, and can be two or more, and those skilled in the art can provide it according to a drift amount of floating fan <NUM>. For example, when there are a plurality of the peak sections <NUM>, the length of the peak sections <NUM> can be set so that the dynamic cable <NUM> can meet the requirement that the drift amount of the floating fan <NUM> is twice the depth of water or more. Each buoyancy unit is correspondingly provided at the top of one peak section <NUM>, that is, heights of parts of the dynamic cable <NUM> at both sides of the buoyancy unit are less than a height of a position of the dynamic cable <NUM> where the buoyancy unit is installed. Each connection unit <NUM> is correspondingly provided on a side of one peak section <NUM> away from the floating fan <NUM>, and when the floating fan <NUM> drifts, the first valley section <NUM>, the second valley section <NUM> and the peak section <NUM> can meet the drift of the floating fan <NUM> through deformation, and when the floating fan <NUM> returns to its original position, the first valley section <NUM>, the second valley section <NUM> and the peak section <NUM> also return to their original positions so that the line shape of the dynamic cable <NUM> returns to its preset state, that is, a state before the floating fan <NUM> drifts.

Those skilled in the art can understand that the buoyancy unit and the connection unit <NUM> provided on the dynamic cable <NUM> are used to define the line shape of the dynamic cable <NUM>, so that the dynamic cable <NUM> can meet the drift of the floating fan <NUM>. The connection unit <NUM> includes the mooring chain <NUM> and the elastic cable. The mooring chain <NUM> and the elastic cable limit the maximum distance between the position, where the dynamic cable <NUM> connects with the mooring chain <NUM>, and the seabed <NUM>, so as to prevent the dynamic cable <NUM> as a whole from drifting in a wide range under adverse conditions, such as an impact of currents in a direction perpendicular to the line shape of the dynamic cable <NUM>, and thus prevent the dynamic cable <NUM> from collision with the anchor chain of floating fan <NUM> or the floating fan <NUM>, and furthermore, the elastic cable <NUM> will stretch elastically when the dynamic cable <NUM> is subjected to a large impact, so as to absorb the impact load on the dynamic cable <NUM>. The dynamic cable <NUM> can have a high degree of integrity, that is, the structure of the dynamic cable <NUM> will not be damaged by the collision, ensuring stability of the dynamic cable <NUM> in transmitting power and/or signals.

As shown in <FIG>, the elastic cable <NUM> includes a first connecting plate <NUM>, a second connecting plate <NUM> and a spring <NUM>. Exemplarily, shapes of the first connecting plate <NUM> and the second connecting plate <NUM> can be circular, and the first connecting plate <NUM> and the second connecting plate <NUM> may be equal in size. The first connecting plate <NUM> is parallel to the second connecting plate <NUM>, the first connecting plate <NUM> is provided above the second connecting plate <NUM>, one end of the spring <NUM> is fixed to the first connecting plate <NUM>, and the other end of the spring <NUM> is fixed to the second connecting plate <NUM>. It is easy to understand that number of the spring <NUM> is not limited. Schematically, there are a plurality of springs <NUM>, and the plurality of springs <NUM> are uniformly provided around an axis of the first connecting plate <NUM> and the second connecting plate <NUM>. A through hole is provided in the middle of the first connecting plate <NUM>, and a part of the mooring chain <NUM> near the bottom end of the mooring chain <NUM> passes through inside the through hole of the first connecting plate <NUM> and is fixedly connected with the first connecting plate <NUM>. Where, the mooring chain <NUM> and the through hole of the first connecting plate <NUM> can be fixed in many ways. For example, the mooring chain <NUM> can be fixed to the first connecting plate <NUM> by welding after passing through the through hole of the first connecting plate <NUM>. Those skilled in the art can understand that when the impact borne by the dynamic cable <NUM> is too large, the spring <NUM> between the first connecting plate <NUM> and the second connecting plate <NUM> extends, so that it can play a buffering role. That is to say, the elastic cable <NUM> absorbs the impact load on the dynamic cable <NUM> through elastic extension to avoid the damage to the dynamic cable <NUM> at the position where the dynamic cable <NUM> is connected with the mooring chain <NUM> due to excessive impact.

As shown in <FIG>, the connection unit <NUM> also includes a monitoring component <NUM> and an anchor <NUM>. The monitoring component <NUM> is provided with a wireless communication module, that is, the monitoring component <NUM> can be communicatively connected to a remote device through the wireless communication module. Exemplarily, the wireless communication module includes acoustic energy converter and acoustic wave transmitter, the remote device includes acoustic wave receiver system, and meanwhile, the remote device is provided with a display component, and a worker can know status of the dynamic cable <NUM> through information displayed by the display component. A main body of the monitoring component <NUM> is fixedly connected with the dynamic cable <NUM>, and the monitoring component <NUM> is also provided with a power transmission line connected with the main body of the monitoring component <NUM>. Exemplarily, the main body of the monitoring component <NUM> also includes a stress module, a displacement module and a temperature module, where the stress module is used to monitor stress at a position where the dynamic cable <NUM> is connected with the monitoring component <NUM>, and it can be a stress sensor; the temperature module is used to monitor temperature at the position where the dynamic cable <NUM> is connected with the monitoring component <NUM>, and it can be an infrared temperature sensor; the displacement module is used to monitor height at the position where the dynamic cable <NUM> is connected with the monitoring component <NUM>, and it can be a radar displacement sensor or a laser displacement sensor and the like. The stress module, displacement module and the temperature module are connected to the remote device through wireless communication module, so that a remote worker can know a specific status of the dynamic cable <NUM> through the remote device. This embodiment does not limit structure of the monitoring component <NUM> here, those skilled in the art can select any suitable monitoring component <NUM> according to actual needs, and of course, they can select a commercially available monitoring component <NUM>.

In one possible implementation, a power transmission line of the monitoring component <NUM> is provided with an armor layer to ensure that the power transmission line of the monitoring component <NUM> has sufficient tensile strength. The mooring chain <NUM> is the power transmission line of the monitoring component <NUM>, that is, the power transmission line of the monitoring component <NUM> is used as the mooring chain <NUM>. This embodiment does not limit the structure of the monitoring component <NUM> here. Those skilled in the art can select any suitable monitoring component <NUM> according to actual needs, and of course, they can select a commercially available monitoring component <NUM>. The anchor <NUM> is fixedly connected with the seabed <NUM>. <FIG> shows that the anchor <NUM> can be a rectangular block structure, and can be buried inside the seabed <NUM> or fastened to the seabed <NUM> through a pin. Of course, the anchor <NUM> may also be in other suitable shapes, and those skilled in the art can select the shape of the anchor <NUM> according to actual needs. The second connecting plate <NUM> is installed on top of the anchor <NUM>. Exemplarily, the second connecting plate <NUM> may be installed to the top of the anchor <NUM> through a fastener such as screw. An interior of the anchor <NUM> is provided with a power supply, which may be a battery or other power supply device. A bottom end of the power transmission line passes through a through hole of the second connecting plate <NUM> and is connected with the power supply inside the anchor <NUM>.

Those skilled in the art can understand that by providing the monitoring component <NUM> and using the power transmission line of the monitoring component <NUM> as the mooring chain <NUM>, the monitoring component <NUM> can monitor the stress and displacement status at the position where the dynamic cable <NUM> is connected with the mooring chain <NUM>. When the stress and the displacement at the position exceeds a preset value, for example, when the stress at the position where the dynamic cable <NUM> is connected with the mooring chain <NUM> is too large or there are too many marine organisms attached to the dynamic cable <NUM>, the monitoring component <NUM> may send an alarm signal to the remote device through the wireless communication module to remind the worker of the abnormal condition of the dynamic cable <NUM>.

It is worth mentioning that a part of the power transmission line of the monitoring component <NUM> between the first connecting plate <NUM> and the second connecting plate <NUM> has a length longer than the maximum length to which the spring <NUM> can be stretched. That is to say, the part of the power transmission line of the monitoring component <NUM> between the first connecting plate <NUM> and the second connecting plate <NUM> has a certain reserve to ensure that the spring <NUM> of the elastic cable <NUM> will not be pulled off when it is stretched.

<FIG>, <FIG>, <FIG> and <FIG> show that the first end of the dynamic cable <NUM> is also provided with a bend limiting cylinder <NUM>, which is made of an elastic material such as polyester amine. Use of the flexible material for making the bend limiting cylinder <NUM> allows the bend limiting cylinder <NUM> to have a small amount of bending. The bend limiting cylinder <NUM> is formed as a conical structure. A large diameter end of the conical structure is provided with a plurality of bolts <NUM> which are fastened to the floating fan <NUM>. Exemplarily, the plurality of bolts <NUM> are spaced around an axis of the bend limiting cylinder <NUM>, and the bolts <NUM> extend in a direction parallel to the axis of the bend limiting cylinder <NUM>. It is easy to understand that the floating fan <NUM> is provided with a flange for fastening to the large diameter end of the bend limiting cylinder <NUM>. The flange is provided with a plurality of through holes matching with the bolts <NUM>, and the large diameter end of the bend limiting cylinder <NUM> can be fastened to the floating fan <NUM> through the bolts <NUM> and the flange. It is worth mentioning that a central part of the bend limiting cylinder <NUM> is provided with a through hole which is coaxial with the bend limiting cylinder <NUM>. The first end of the dynamic cable <NUM> is provided to pass inside the conical structure, this is, pass through the through hole in the central part of the bend limiting cylinder <NUM>, and is fixedly connected with the floating fan <NUM>.

Those skilled in the art can understand that the first end of the dynamic cable <NUM> is provided with the bend limiting cylinder <NUM>, the bend limiting cylinder <NUM> is formed into a conical structure and the large diameter end of the conical structure is fastened to the floating fan <NUM>, the first end of the dynamic cable <NUM> is provided to pass inside the conical structure and is fixedly connected with the floating fan <NUM>, the bend limiting cylinder <NUM> wrapped at the first end of the dynamic cable <NUM> can prevent excessive bending of the dynamic cable <NUM> at the position where the dynamic cable <NUM> is connected with the floating fan <NUM>, and thus, the first end of the dynamic cable <NUM> can be prevented from being damaged due to stress concentration, and transmission stability of the dynamic cable <NUM> can be guaranteed.

Preferably, as shown in <FIG> and <FIG>, the axis of the bend limiting cylinder <NUM> is set obliquely. Exemplarily, when the floating fan <NUM> does not drift, an extension direction of the axis of the bend limiting cylinder <NUM> is the same as that of the first end of the dynamic cable <NUM>.

As shown in <FIG> and <FIG>, the buoyancy unit includes a plurality of buoyancy blocks <NUM>, which are fastened to the dynamic cable <NUM>. It is easy to understand that the buoyancy blocks <NUM> may be made of a buoyant material, and a density of the buoyant material is less than the density of sea water, so that the buoyancy blocks <NUM> may provide upward buoyancy for the dynamic cable <NUM> in the sea water. Exemplarily, the buoyant blocks <NUM> are formed as a cylindrical structure, and the buoyant blocks <NUM> are sleeved on the dynamic cable <NUM>, and are fastened to the dynamic cable <NUM>. It is worth mentioning that a cross section of the buoyancy blocks <NUM> is not limited to a circular shape. For example, the cross section of the buoyancy blocks <NUM> may also be in any suitable shape such as square shape or polygonal shape. The plurality of buoyancy blocks <NUM> are arranged at intervals along the extension direction of the dynamic cable <NUM>. It is easy to understand that the number of the buoyancy blocks <NUM> in each buoyancy unit is not limited, and those skilled in the art can set them according to actual needs. Setting the number of the buoyant blocks <NUM> as plurality can increase net buoyancy of the buoyant unit, so that load-bearing capacity of the dynamic cable <NUM> can be increased, and it is not easy for marine organisms such as seashells and seaweeds breeding on the dynamic cable <NUM> to lower the line shape of the dynamic cable <NUM>, thus reducing the risk of collision between the dynamic cable <NUM> and the seabed <NUM>.

It is worth mentioning that for the existing dynamic cable <NUM>, in order to make the line shape of the dynamic cable <NUM> form a preset shape, volume of the buoyancy material of the buoyancy block <NUM> need to be accurately calculated to make net buoyancy of the buoyancy unit reach a preset value. For the dynamic cable assembly provided in this embodiment, the dynamic cable <NUM> is connected with the seabed <NUM> through the elastic cable <NUM> and the mooring chain <NUM> of the connection unit <NUM>, the net buoyancy of the buoyancy unit can exceed the preset value of the buoyancy unit in the existing dynamic cable assembly, and the elastic cable <NUM> and the mooring chain <NUM> can prevent the dynamic cable <NUM> from rising to the sea surface <NUM> under the buoyancy of the buoyancy block <NUM>. That is to say, design and selection of the buoyancy block <NUM> of the dynamic cable assembly provided by this embodiment has a large margin, and at the same time, an assembling error and a construction error of the buoyancy block <NUM> also have a large margin, and thus assembling efficiency of the dynamic cable assembly can be improved.

Exemplarily, a spacing between two adjacent buoyancy blocks <NUM> in the buoyancy unit is <NUM>-<NUM> times the length of the buoyancy blocks <NUM>. Those skilled in the art can understand that the dynamic cable <NUM> bends downward between the two adjacent buoyancy blocks <NUM> under the action of its own gravity, and setting the spacing between the two adjacent buoyancy blocks <NUM> as <NUM>-<NUM> times the length of the buoyancy blocks <NUM> can avoid excessive bending of the dynamic cable <NUM> in an area between the two buoyancy blocks <NUM>, thus ensuring the stability of the dynamic cable <NUM> in transmission of the power and/or signals.

As shown in <FIG> and <FIG>, it is worth mentioning that the main body of the monitoring component <NUM> is connected with the dynamic cable <NUM> through a bend limiting caliper <NUM>, the bend limiting caliper <NUM> is used to limit a bending radius at the position where the dynamic cable <NUM> is connected with the mooring chain <NUM>, namely, the power transmission line of the monitoring module <NUM>, to avoid rupture of the outer sheath of the dynamic cable <NUM> and failure of functional units of the dynamic cable <NUM> due to the stress concentration caused by excessive bending of the dynamic cable <NUM>. Specifically, the bend limiting caliper <NUM> includes a clamping section <NUM> and two cone sections <NUM>, where the two cone sections <NUM> are respectively located at two sides of the clamping section <NUM>, the cone sections <NUM> are made of an elastic material such as polyester amine so that the cone sections <NUM> can be slightly bent. Large diameter ends of the cone sections <NUM> are fixedly connected with the clamping section <NUM>, for example, the large diameter ends of the cone sections <NUM> can be fixed to the clamping section <NUM> through a flange. The dynamic cable <NUM> is provided to pass inside the two cone sections <NUM>, and the clamping section <NUM> is fastened to a portion of the dynamic cable <NUM> located between the two cone sections <NUM>. <FIG> show that the clamping section <NUM> includes two buckled parts, and the two buckled parts define a cylindrical structure. During the assembling of the clamping section <NUM> and the dynamic cable <NUM>, the dynamic cable <NUM> is provided to pass between the two buckled parts and is clamped by the two buckled parts. The two buckled parts can be fastened by a fastener. Further, a glue can be injected between the dynamic cable <NUM> and the two buckled parts to improve stability of connection between the dynamic cable <NUM> and the clamping section <NUM>. The dynamic cable <NUM> being provided to pass inside the two cone sections <NUM> and a portion of the dynamic cable <NUM> between the two cone sections <NUM> being clamped by the two buckled parts of the clamping section <NUM> can also increase fatigue resistance of the dynamic cable <NUM>, that is, the dynamic cable <NUM> is not easy to break when repeatedly bent, thus improving the service life of the dynamic cable <NUM>. The main body of the monitoring component <NUM> is fastened to the clamping section <NUM>. For example, the main body of the monitoring component <NUM> can be fastened to the clamping section <NUM> of the bend limiting caliper <NUM> by a screw.

As shown in <FIG> and <FIG>, the dynamic cable assembly also includes a clump weight <NUM>, the clump weight <NUM> is fastened to the dynamic cable <NUM>, and is installed to the first valley section <NUM>. Exemplarily, the clump weight <NUM> is also a cylindrical structure defined by the two buckled parts. The clump weight <NUM> is sleeved on the dynamic cable <NUM> and fastened to the dynamic cable <NUM>. It is easy to understand that a density of material of the clump weight <NUM> is greater than that of the sea water, so that when the clump weight <NUM> is fastened to the dynamic cable <NUM>, the clump weight <NUM> can exert downward gravity on the dynamic cable <NUM>. Where there may be a plurality of clump weights <NUM>, and the plurality of clump weights <NUM> are set at intervals along the extension direction of the dynamic cable <NUM>. Those skilled in the art can understand that by providing the clump weight <NUM> on the dynamic cable <NUM>, the clump weight <NUM> exerts a downward gravity on the dynamic cable <NUM>, and the gravity of the clump weight <NUM> can prevent a part of the dynamic cable <NUM> between the floating fan <NUM> and the buoyancy unit from floating above the sea surface <NUM>. In addition, the gravity of the clump weight <NUM> and the buoyancy of the buoyancy unit make the line shape of the dynamic cable <NUM> include the first valley section <NUM> connected with the floating fan <NUM> and the peak section <NUM> connected with the first valley section <NUM>. That is to say, by providing the clump weight <NUM>, the dynamic cable <NUM> can form a preset line shape in the sea water, thus improving the ability of the dynamic cable <NUM> to resist the impact of currents and waves.

This embodiment also provides a shallow water floating wind power system, including a floating fan, a static cable and the dynamic cable assembly in Embodiment <NUM>.

The floating fan floats on the sea surface, exemplarily, the floating fan includes a fan, a central tower and a floating platform, where the fan may be three-bladed, and the fan is installed to top of the central tower, a bottom of the central tower is provided on the floating platform, the floating platform may be, for example, a Spar (single-column), barge or semi-submersible platform, which is not limited in this embodiment. The static cable is fixed to a seabed, for example, the static cable may be fastened to a surface of the seabed by a fastener. One end of the dynamic cable in the dynamic cable assembly is electrically connected with the floating fan, for example, one end of the dynamic cable may be suspended from the floating platform of the floating fan and electrically connected with the fan on the floating platform, and the other end thereof is electrically connected with the static cable, so that when sea wind drives the fan to rotate, power generated by the fan can be transmitted by the dynamic cable and the static cable.

Since the shallow water floating wind power system provided by this embodiment uses the dynamic cable assembly in Embodiment <NUM>, when the sea condition is severe, the dynamic cable will not drift in a wide range and thus will not collide with the floating fan or the anchor chain of the floating fan, which results in failure.

In the description of the present application, it is necessary to understand that orientation or position relationship indicated by the terms "top", "bottom", "up", "down" (if any) is based on the orientation or position relationship shown in the accompanying drawings, and is only for the convenience of describing the present application and simplifying the description, rather than indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation. Therefore, they cannot be understood as a limitation of the present application.

In the description of the present application, it should be noted that unless otherwise specified and defined, the terms "installation", "attachment" and "connection" should be understood in a broad sense, for example, they can be fixed connection, removable connection, or integrated connection; they can be mechanical connection or electrical connection; they can be directly connected, or indirectly connected through an intermediate medium, or they can be internal communication of two components. For those skilled in the art, the specific meanings of the above terms in the present application can be understood according to specific circumstances.

The terms "first" and "second" in the description, claims and the above brief description of the drawings of the present application are used to distinguish similar objects, and are not necessarily used to describe a particular order or sequence. It should be understood that figures used in this way can be interchanged in appropriate cases, so that the embodiments of the present application described herein for example can be implemented in an order other than those illustrated or described herein.

Claim 1:
A dynamic cable assembly for a shallow water floating wind power system, comprising;
a dynamic cable (<NUM>), a first end of which is used to connect a floating fan (<NUM>), and a second end of which is used to connect a static cable;
a plurality of buoyancy units, provided on the dynamic cable at intervals;
a plurality of connection units, each comprising a mooring chain (<NUM>) and characterized in that the plurality of connection units further comprise an elastic cable,
wherein a bottom end of the elastic cable is fixedly connected with a seabed, a top end of the elastic cable is fixedly connected with a portion of the mooring chain near a bottom end of the mooring chain, and a top end of the mooring chain is fixedly connected with the dynamic cable;
the connection units and the buoyancy units jointly define a line shape of the dynamic cable, the line shape of the dynamic cable comprises a first valley section (<NUM>) connected with the floating fan, a plurality of peak sections (<NUM>) connected with the first valley section and a second valley section (<NUM>) between two adjacent peak sections; each buoyancy unit is correspondingly provided at top of one peak section, and each connection unit is correspondingly provided at a side of one peak section away from the floating fan.