KR101283670B1 - Foundation unit for tripod type wind power generation plant on the sea - Google Patents

Abstract

The present invention relates to a tricycle-type offshore wind power foundation, and more specifically, a tripod-type offshore wind power generation that can increase economics and work productivity by making a tetrapod-shaped concrete body in advance and installing it on the sea floor. It is about basic materials.
To this end, the three fixed poles are fixed to the triangular point of the seabed, made of a hollow pipe; three support parts each formed with an insertion hole through which the fixing pole passes, and each of the support parts is integrated Concrete body consisting of an installation portion extending upward from the center portion and the head and the main post of the wind power installation; The guide member is formed on the upper surface formed with the insertion hole of the concrete body, extending upward from the edge of the insertion hole: including Provides a tricycle type offshore wind power foundation.

Description

Foundation for tripod type wind power generation plant on the sea}

The present invention relates to a tricycle type offshore wind power foundation, and more particularly, to a tricycle type offshore wind power foundation that can be manufactured on land beforehand and can improve economic efficiency and work productivity.

Offshore wind power generation refers to a power generation system in which a wind turbine is installed in a lake, a fjord terrain, or a coastal waterside, and the kinetic energy of the wind blowing there is converted into mechanical energy by rotating wings to obtain electricity.

Offshore wind power facilities are largely divided into generators and foundations.

First, turbines basically apply the same technology as onshore wind power heads. It has a lifespan of about 20 years and is applied to wind turbines larger than 3 ~ 5MW which are larger than onshore. Each element is designed and coated to prevent corrosion damage due to salt.

And, Foundation can be explained by dividing into four representative types.

Concrete caisson type, monopile type, jacket type, floating type can be provided. Among them, concrete caisson type is easy to manufacture and install, so it is used for the early offshore wind farm. Vindeby) and Middelgrunden offshore wind farms.

It can be used at relatively shallow depths of 6 ~ 10m and maintains its position due to friction between its own weight and the sea floor.

The foundation diameter of the concrete type is approximately 12-15 m.

Hereinafter, a brief description of the method for constructing the foundation of the concrete type as follows.

In the case of offshore structures, after drilling is carried out including boring or drilling method and angle of repose, the discarded concrete is poured and the structure for mounting anchor bolt is installed.

Thereafter, after placing the deformed reinforcing bar by constructing the formwork to pour concrete, the concrete type foundation work is completed.

However, the basic construction according to the prior art has the following problems.

First, the basic production of the formwork method, because the production process and installation process is provided separately, there was a problem that takes a long time to complete the basic construction.

Second, when the vertical load is 800ton or more, the conventional basic construction method is to examine the load on the basis of the anchor bolts discussed above, and when the gripping force is insufficient, it is common to configure the anchor bolts in a two-row and three-row array format.

At this time, the base material selection process for offshore structures with a load of 800t or more must be considered from geological survey to resistance concrete in earth pressure. Therefore, to calculate and apply anchor bolt, embedded, and bracket separately, It is difficult to grasp bearing capacity, and it is difficult to apply and prevent over factor application.

In other words, the conventional foundation work can be a huge large-scale civil engineering work, there is a problem that the cost of the foundation construction is increased and economic efficiency is lowered.

The present invention has been made to solve the above problems, an object of the present invention is to provide a tri-type offshore wind power generator base material to reduce the installation cost and improve the workability by construction on the seabed in advance in the land. .

The present invention, in order to achieve the above object, is fixed to the triangular point of the seabed, three fixed poles made of a hollow pipe; three support parts each formed with an upper and lower through-holes to pass through the fixed pole, A concrete body comprising an installation unit in which each support unit is extended upward from an integrated central unit to install a turbine of a wind power generation facility; formed on an upper surface of the concrete body in which an insertion hole is formed, and extending upward from an edge of the insertion hole Guide member: provides a trivet type offshore wind power foundation comprising a.

At this time, the concrete body is preferably in the form of tetrapod (Tetrapod).

In addition, the concrete body is preferably coated with a concrete protective coating.

In addition, a fixing hole for fixing with the fixing pole is formed in the guide member, a fastening hole communicating with the fixing hole is formed in a portion corresponding to the fixing hole among the fixing poles, and guides to the fixing pole through the fixing hole and the fastening hole. It is preferable that a fixing pin is provided to fix the member.

At this time, the concrete body is preferably produced by a truss (truss) method.

The trigeminal offshore wind power foundation according to the present invention has the following effects.

First, since the manufacture of the base material is made onshore, it is installed at sea, so the installation cost is reduced and economic efficiency is high.

Second, there is an effect that the work method is increased because the construction method is simple.

That is, by sliding the base material manufactured on land to a fixed pole embedded in the seabed, it is possible to improve the construction convenience of the operator as well as the convenience of the position guide of the base material as well as the convenience of the construction method.

1 is a perspective view showing a tricycle-type offshore wind power foundation according to a preferred embodiment of the present invention
Figure 2 is a side view showing a state in which the tri-shape offshore wind power foundation is inserted into a fixed pole embedded in the seabed according to a preferred embodiment of the present invention
Figure 3 is a cross-sectional view showing a state in which the triangular offshore wind power foundation is inserted into a fixed pole embedded in the seabed according to a preferred embodiment of the present invention
Figure 4 is a plan view showing a state in which a tri-trip offshore wind power foundation is inserted into a fixed pole embedded in the seabed according to a preferred embodiment of the present invention.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, with reference to the accompanying Figures 1 to 4 will be described with respect to the tri-shape offshore wind power generation base material (hereinafter referred to as "base material") according to a preferred embodiment of the present invention.

The base material serves as the foundation for installing the offshore wind turbines offshore, and is installed on the sea floor.

Base material is installed on the sea floor, but there is a technical feature that can be provided on the sea in the pre-fabricated state to be constructed.

To this end, the base material is configured to include a fixing pole 100, a concrete body 200, a guide member 300, and a fixing pin 400, as shown in FIG.

The fixing pole 100 serves to fix the concrete body 200 to the seabed, and is provided to be fixed to the seabed.

At this time, the fixing pole 100 is provided in the form of a hollow pipe.

This is to maximize the fixing force of the fixing pole 100 to the concrete body 200 by placing concrete in the fixed pole 100 embedded in the seabed.

In addition, the number of fixing poles 100 is provided in three of the characteristics of the concrete body 200.

That is, due to the external characteristics of the concrete body 200 made of trivet form, the fixing pole 100 is also provided in three.

At this time, the fixing pole 100 is fixed to the seabed is fixed, its position is fixed to a triangular point corresponding to the concrete body 200.

In addition, a fixing hole 110 is formed in the fixing pole 100.

Fixing hole 110 is provided for coupling with the guide member 300 to be described later, is formed to penetrate both sides of the fixing pole (100).

Next, the concrete body 200 is a configuration for the foundation of the offshore wind power generator, the site where the wind power generation head is installed.

Concrete body 200 is formed in the form of a heavy weight so that the wind power head can be installed firmly at sea, its weight is preferably provided to be made of about 150 to 300 tons.

Concrete body 200 is made by pouring concrete on land as can be seen through the term, as shown in Figure 1, its shape is made of trivet form.

Sambal is a convenient term for describing the properties of the form, the form of which is actually similar to tetrapod.

And, as described above, the concrete body 200 is manufactured by concrete pouring in the land, it is preferable to be manufactured by the truss (truss) method.

That is, the concrete body 200 is a truss beam is installed inside the fabric for durability and strength.

Concrete body 200 is composed of a support portion 210 which is supported on the seabed, the installation unit 220 is installed on the wind generator (generator) and the post foundation flange (foundation flange).

The support portion 210 is a portion in close contact with the sea bottom and is formed in three directions.

That is, the support 210 is supported at the triangular point of the seabed.

At this time, each of the support portion 210 is formed, the insertion hole 211 through the up and down.

Insertion hole 211 is to ensure that the concrete pole 200 is firmly supported on the seabed so that the fixed pole 100 is embedded in the seabed.

The inner diameter of the insertion hole 211 is formed in a size corresponding to the outer diameter of the fixing pole (100).

In addition, the installation unit 220 is a site where the wind turbine is installed, and the support unit 210 is formed so as to face upward from the integrated central portion.

On the other hand, the surface of the concrete body 200 is preferably coated with a concrete protective coating.

This is to protect the salt from the nature of the concrete body 200 is settled in the sea.

That is, the porosity of the concrete facilitates the penetration of salts, and the physical weakening due to the relatively weak abrasion resistance and cohesion, which eventually leads to corrosion of the truss beam through neutralization and microcracks, resulting in the volume of the truss beam This is to prevent the problem of increase and breakage.

Next, the guide member 300 guides the fixed pole 100 in the process of passing the fixed pole 100 through the insertion hole 211 of the concrete body 200, the fixed pole 100 and the concrete body ( 200) for fixing each other.

The guide member 300 is formed upward from each insertion hole 211 formed in the support portion 210, the inner diameter of the guide member 300 is preferably formed to be the same as the inner diameter of the insertion hole (211).

At this time, the fastening hole 310 is formed in the guide member 300.

The fastening hole 310 is a portion to which the fixing pin 400 to be described below is fastened for coupling with the fixing pole 100, and is formed through both sides of the guide member 300.

At this time, the fastening hole 310 is formed in a form corresponding to the fixing hole of the fixing pole (100).

Next, the fixing pin 400 serves to fix the concrete body 200 coupled to the fixing pole 100 to the fixing pole 100, and the fastening hole 310 and the fixing pole of the guide member 300 ( It is fastened through the fixing hole 110 of the 100.

At this time, the fixing pin 400 is composed of a head 410, the body 420 passing through the fastening hole 310 and the fixing hole 110, the body 420 at the end of the body 420 A through hole 421 is formed therethrough.

In addition, the auxiliary fixing pin 422 is further fastened to the through hole 421, such a configuration to prevent the fixing pin 400 fastened to the fixing pole 100 and the guide member 300 from being separated from the fastened portion. It is for the configuration.

Hereinafter, a process in which the base material having the above configuration is constructed on the sea floor will be described.

Production is made for the concrete body 200 on land.

As described above, in the state in which the frame is made by the truss method, the production is made through concrete pouring.

At this time, the form of the completed concrete body 200 is made of a tricycle, that is, tetrapod form.

On the other hand, apart from the production for the concrete body 200, the fixed pole 100 is driven and fixed to the position of the seabed to be installed in the wind turbine.

At this time, the fixed pole 100 is embedded in a fixed position to form a triangular shape, the fixing hole 100 is exposed to the lower portion of the fixing pole (100).

At this time, the upper position of the fixing pole 100 is up to the sea level.

Thereafter, when the fixing of the fixing pole 100 is completed on the sea floor, a process of sucking the foreign substance introduced into the fixing pole 100 is performed.

This, the fixed pole 100 is formed in the form of a hollow pipe bar, the foreign material, including mud infiltrated into the fixed pole 100 in the process of the fixed pole 100 is embedded in the seabed, fixed later In order to pour concrete into the interior of the pole 100 is to suck the foreign matter inside the fixed pole (100).

Next, when the suction work for the inside of the fixed pole 100 is completed, the concrete body 200 produced on land is carried to the sea to perform the work to be fixed to the fixed pole 100.

At this time, as the concrete body 200 is inserted into the fixing pole 100 through the insertion hole 211 formed in the support portion 210, the concrete body 200 is lowered toward the seabed while being guided by the fixing pole 100. do.

Thereafter, the fastening hole 310 formed in the guide member 300 of the concrete body 200 lowered on the seabed is matched with the fixing hole 110 of the fixing pole 100.

Thereafter, the diver to submerge to the sea floor to perform the operation of fastening the fixing pin 400 to the fixing pole 100 and the guide member 300.

Next, the concrete is poured into the fixing pole 100.

That is, since the fixed pole 100 has a hollow shape, the concrete can be easily poured through the upper portion of the fixed pole 100 exposed to the sea surface.

At this time, the casting of the concrete is not made in the fixed pole 100, it is preferable that the casting is made only up to the upper end position of the guide member (300).

Subsequently, when curing of the concrete is completed in the fixing pole 100, the fixing pole 100 is cut out based on the upper end of the guide member 300.

This completes the construction of the base material on the sea floor.

As described so far, the trivet type offshore wind power foundation according to the present invention has a technical feature that can be easily installed on the seabed in advance in the land.

That is, after the tetrapod-shaped concrete body is manufactured by the truss method on land, the installation work of the base material can be provided very easily by settling on the seabed along the fixed pole embedded in the seabed.

As a result, economics and work productivity are increased.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: fixed pole 110: fixed hole
200: concrete body 210: support
211: insertion hole 220: mounting portion
300: guide member 310: fastening hole
400: fixing pin 410: head
420: body 421: through hole
422: auxiliary pin

Claims (5)

Three fixed poles are fixed to the triangular point of the seabed, consisting of a hollow pipe;
Concrete body consisting of three support parts each formed with the upper and lower through-holes through which the fixed pole passes, and the installation part for installing the head and the main post of the wind power plant, extending upward from the central part where the respective support parts are integrated. ;
The tri-shape offshore wind power generation base member is formed on the upper surface of the concrete body is formed with the insertion hole, the guide member extending upward from the edge of the insertion hole. The method of claim 1,
The concrete body is a tripod offshore wind power generation base material, characterized in that the tetrapod (Tetrapod) form. 3. The method according to claim 1 or 2,
The trivet-type offshore wind power generation base material, characterized in that the concrete body is coated with a protective coating coating. 3. The method according to claim 1 or 2,
The guide member is formed with a fixing hole for fixing with the fixing pole, a portion of the fixing pole corresponding to the fixing hole, a fastening hole communicating with the fixing hole is formed,
Tri-type offshore wind power generation base material characterized in that the fixing pin for fixing the guide member to the fixed pole through the fixing hole and the fastening hole. 3. The method according to claim 1 or 2,
The concrete body is a trivet type offshore wind power generation base material, characterized in that produced by the truss (truss) method.

Images