KR20190129197A - Pillars for supporting structures - Google Patents

Abstract

According to the present invention, a column for supporting a structure includes: a column main body provided with the hollow inside; and a support unit provided in the column main body and supporting a structure positioned on an upper portion in accordance with a water level of water introduced into the column main body. The column for supporting a structure of the present invention is possible to support a load or self-weight of the structure having self-weight such as a building and a bridge without a structural change of the column or reconstruction of the column by storing the water in the column and adjusting the water level.

Description

Pillar for supporting structures {PILLARS FOR SUPPORTING STRUCTURES}

The present invention relates to a pillar for supporting a structure, and more particularly, to support the weight of a structure such as a building or a bridge by using the buoyancy of water stored or introduced into the column and the elastic support of the elastic member provided in the column. The present invention relates to a pillar for supporting a structure.

Structures with loads, such as buildings, bridges, and the like, may be supported by columns.

At this time, when the building is newly built, if the weight or load of the structure to be supported by the pillar is large, it is necessary to increase the size of the pillar by increasing the diameter or thickness of the pillar. In addition, it may be necessary to review the height of the column and the shape of the cross section.

However, when the size of the pillar of the structure is increased as described above, there is a problem of increasing the construction cost of the pillar as well as increasing the construction cost of the structure itself. In other words, increasing the size of the pillar supporting the structure without increasing the size of the structure results in uneconomical design of the structure.

On the other hand, the recent remodeling of buildings has been increasing. In case of remodeling such as remodeling or rebuilding the building such as apartment or house as well as changing the design live load due to the change of internal space of the building, it must be able to support the increasing load of the building as the column supporting the building is expanded. . If the original column cannot support the load of the building to be expanded, new columns with larger diameters or thicknesses must be newly constructed as described above, which may lead to an increase in construction cost and an extension of the construction period.

If it is possible to support the load of various sizes with a single column within the use cycle of the building, expansion or reconstruction of the building, etc. may be further activated. Therefore, it is expected that there will be an increasing demand for a technology that enables a single column to support structures of various sizes or loads of varying sizes.

Meanwhile, there is a possibility that water shortage problems will intensify in the future as the number of clean water available due to drought frequency and water pollution caused by climate change is reduced worldwide. In Korea, 2,591 mm of precipitation per person per year is about 1/8 of the world average. However, in Korea, most of the precipitation is concentrated in some periods such as summer, so it is very difficult to efficiently use and manage water resources.

Moreover, in urban areas there are many paved and impermeable asphalt roads, so most of the natural rainwater is designed to flow into rivers. If the used water can be reused in the above column, it will not only respond to climate change or future water shortage, but also expect the additional effect of water resource recycling.

Accordingly, the present applicant has proposed the present invention to solve the above problems, and as related prior art documents, Japanese Unexamined Patent Publication No. 2003-020611 (Invention: Subsidiary Substructure, Publication Date: 2003.01 .24.)

An object of the present invention is to provide a pillar for supporting a structure that can support a structure having a load of various sizes with a single pillar.

In addition, the present invention is to provide a pillar for supporting a structure that can cope with the case that the weight of the structure is changed when the remodeling or repurpose of the structure, such as expansion or reconstruction of the structure by adjusting the amount of water stored in the column.

The problem to be solved by the present invention is not limited to the above-mentioned problem, another task that is not mentioned will be clearly understood by those skilled in the art from the following description.

The above object, according to the present invention, the pillar body is provided hollow inside; And a support unit provided in the pillar body to support a structure positioned above the structure according to the level of water introduced into the body.

The support unit, the lifting member is provided in the interior of the column body to be raised or lowered according to the level of water flowing into or stored in the column body; A structure support plate provided in the pillar body and in contact with the structure; And a support force generating member connected to the structure supporting plate and the elevating member and floating on water introduced into the pillar body to create a force supporting the structure.

The bearing force generating member may generate a force of a different size according to the size of the space formed between the lifting member and the structure supporting plate.

The bearing force generating member may generate a greater force as the lifting member rises.

The supporting force generating member may be reduced in length when the lifting member is raised to push the structure supporting plate, and may be loosened when the lifting member is lowered to release the compression.

The bearing force generating member may be provided as a compression coil spring.

A sealing member may be provided on the outer circumferential surface or the circumferential surface of the elevating member.

A stopper is formed inside the pillar body, and as the level of water introduced into the pillar body increases, the stopper may be provided at the highest position of the elevating member to stop the elevating member. A sensor for detecting the height of the elevating member or the water level may be provided.

A water supply pump may be provided to additionally supply water to the inside of the pillar body according to the sensing value of the sensor.

The pillar for supporting the structure of the present invention can support various loads or own weights of structures having self weights such as buildings, bridges, etc. without changing the structure of the columns or rebuilding the columns by storing water in the columns but adjusting the water level.

Further, the pillar for supporting the structure of the present invention can support only the pillar of a small size when the weight of the structure to be supported is large, so that the construction cost of the structure as well as the pillar can be reduced.

In addition, the pillar for supporting the structure of the present invention can adjust the amount of water stored in the pillar can easily cope with the change in the weight of the support structure according to the remodeling, such as expansion or reconstruction of the structure or change of use.

In addition, the pillar for supporting the structure of the present invention, by introducing water into the structural member of the structure in terms of zero energy inside the structure, such as buildings, bridges, the strength is not simply zero energy in terms of energy saving LCC (life cycle cost) of the structure Zero energy may be possible before use of the structure in terms of improvement and material cost savings.

In addition, the pillar for supporting the structure of the present invention can contribute to the efficient use of water resources by utilizing the discarded water or rainwater (rainwater) to support the structure.

1 to 3 is a schematic cross-sectional view of the pillar for supporting the structure according to an embodiment of the present invention.
4 is a schematic cross-sectional view of a modified example of the pillar for supporting the structure according to the embodiment of the present invention shown in FIGS.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

It is noted that the figures are schematic and not drawn to scale. The relative dimensions and ratios of the parts in the figures have been exaggerated or reduced in size for clarity and convenience in the figures and any dimensions are merely exemplary and not limiting. And the same reference numerals are used to refer to similar features in the same structure, element or part shown in more than one figure.

Embodiments of the present invention specifically illustrate ideal embodiments of the present invention. As a result, various modifications of the drawings are expected. Thus, the embodiment is not limited to the specific form of the illustrated region, but includes, for example, modification of the form by manufacture.

Hereinafter, with reference to the accompanying drawings will be described a pillar for supporting the structure 100 according to an embodiment of the present invention.

1 to 3 is a schematic cross-sectional view of the pillar for supporting the structure according to an embodiment of the present invention and FIG. 4 is a schematic diagram of a modification of the pillar for supporting the structure according to the embodiment of the present invention shown in FIGS. It is a cross-sectional view.

1 to 4, the structure support pillar 100 according to an embodiment of the present invention is provided in the interior of the pillar body 110 and the pillar body 110 is provided with a hollow inside, the pillar body ( It may include a support unit 120 for supporting the structure 10 placed on the top of the column body 110 by floating (floating) by the water flowing into or stored in the interior of the 110.

First, the pillar body 110 is a main member for supporting the structure 10. The pillar body 110 may be provided with a hollow to store water therein and a support unit 120. Here, the water stored in the pillar body 110 may be rainwater generated by rain or snow or water forcibly supplied by an operator. Here, it is preferable that the water forcibly supplied is recyclable water such as sewage.

Although the pillar body 110 may be formed of various materials, it is preferable that the pillar body 110 is generally made of steel or concrete.

Here, the structure 10 may be a structure that is built having its own weight, such as buildings, bridges. In this case, the pillar body 110 may be integrally formed with the structure 10 or may be separately formed. That is, the pillar body 110 is installed together at the time of construction of the structure 10 by using the support unit 120 provided in the interior of the pillar body 110 and water introduced into the pillar body 110. It can support the weight of (10).

If the pillar body 110 is integrally formed with the structure 10, rainwater or rain may be impossible to flow into the pillar body 110.

In this case, the worker needs to forcibly water the inside of the pillar body 110. Accordingly, as shown in Figures 1 to 4, the column body 110 is connected to the water supply valve 140 and the water supply pump 150, if necessary to force water from the outside to the inside of the column body 110 You can water with

In this case, a water storage tank (not shown) may be connected to the feed pump 150, or a recycling water line (not shown) such as a sewer may be connected. In addition, the water supply valve 140 and the water supply pump 150 is preferably connected to a control unit (not shown) for detecting or calculating the flow rate or level of the water flowing into or stored in the column body 110. The control unit may receive information about the flow rate supplied to the column body 110, the water level or the water level change of the water stored in the column body 110.

On the other hand, as described above, the pillar body 110 may be formed of concrete instead of being formed of a steel material. When the pillar body 110 is formed of concrete, a plurality of reinforcing bars may be arranged inside the concrete.

In addition, the pillar body 110 may be formed of a single-pipe or concrete single pipe or may be formed of a double-pipe. When the pillar body 110 is formed of a double pipe, the steel single pipe and the concrete single pipe may be provided in a form arranged inside and outside.

The pillar body 110 may be fixed to the support surface by the support block 112. The support block 112 is preferably positioned to support both sides of the lower end of the column body 110 in the width direction, and may be made of the same material as the pillar body 110. For reference, the support block 112 may not be positioned depending on the form and state in which the pillar body 110 is embedded in the support surface. Here, the support surface may be the ground or may be the floor surface of the building.

On the other hand, the support unit 120 may be provided in the interior of the pillar body 110 may be provided to float in the water flowing into or stored in the interior of the pillar body (110). The support unit 120 is a portion supporting the structure 10 together with the pillar body 110.

The support unit 120 may be provided in a space formed between an upper end of the pillar body 110, that is, a lower surface of the structure 10 and a water surface provided in the pillar body 110. The size of the space S is changed according to the water level or quantity of water provided in the pillar body 110, and the force of the support unit 120 also varies according to the size change of the space. In this way, by varying the force of the support unit 120 can support a variety of loads of the structure (10).

Here, the smaller the size of the space, the greater the force that the support unit 120 has. When it is necessary to support the structure 10 with a larger load by expanding the building, it is preferable to increase the force of the support unit 120 by reducing the size of the space.

As the size of the space S decreases, the support unit 120 has the lifting member 124 and the pillar member 110 that rise or fall along the inner surface of the pillar member 110. It may include a structure support plate 122 provided on the top and directly supporting the structure 10 and the lifting force generating member 126 for connecting the lifting member 124 and the structure support plate 122.

First, the elevating member 124 may be raised or lowered along the inner surface of the column body 110 according to the water level introduced into the column body 110 or stored in the column body 110.

Also, the elevating member 124 may be provided in the form of a circular plate or sphere having buoyancy. However, the shape of the elevating member 124 may be changed in any form as long as it is formed in a form capable of raising or lowering inside the pillar body 110.

The lifting member 124 is preferably provided with a size slightly smaller than the inner diameter of the column body (110). For example, when the diameter of the elevating member 124 is equal to or larger than the inner diameter of the column body 110, the elevating member 124 is raised or lowered depending on the amount or level of water introduced into the column body 110. It may be impossible to descend. In addition, when the diameter of the elevating member 124 is equal to or larger than the inner diameter of the column body 110, it may not be possible to provide a sealing means on the circumferential surface of the elevating member 124.

The elevating member 124 may be formed of a material that may have a buoyancy sufficient to float on the water surface. However, when the supporting force generating member 126 is compressed, the lifting member 124 may be hard enough to sufficiently support the force of the supporting force generating member 126, that is, the elastic supporting force.

A sealing member 125 formed of a rubber material may be formed on the circumferential surface or the outer circumferential surface of the elevating member 124. Accordingly, the lifting member 124 may serve as a piston.

Since the sealing member 125 is provided on the outer circumferential surface of the elevating member 124, when the elevating member 124 ascends or descends according to the water level flowing into the column body 110, the elevating member 124 may be formed. Prevents air from flowing into the column body 110 below the height or prevents water below the elevating member 124 from escaping over the elevating member 124 beyond the elevating member 124. can do. Then, since the elevating member 124 can stably float to the water stored in the pillar body 110, the structure supporting plate 122 which has received the elastic supporting force of the supporting force generating member 126 as it is is the structure 10. Can stably support

For reference, since the elevating member 124 is provided to be smaller than or equal to the inner diameter of the pillar body 110, the rain is stored in the interior of the pillar body 110 as the time for using the structure support pillar 100 elapses. Alternatively, the water may evaporate, reducing the water level or yield. Here, the sealing member 125 may also function to prevent evaporation of water.

On the other hand, the structure supporting plate 122 may be provided on the upper portion of the column body 110 may be in contact with the lower end of the structure (10). At this time, the structure supporting plate 122 is also preferably formed in the form of a plate.

Here, although not shown in Figures 1 to 4, the structure support plate 122 may be formed integrally with the structure 10 located on the top. That is, the structure constituting the bottom of the structure 10 may be formed of the structure support plate 123.

On the other hand, the support force generating member 126 is connected to the structure supporting plate 122 and the elevating member 124, the force of different sizes depending on the level of water introduced into the column body 110 or the size of the space (S) It is a member to produce. The support unit 120 supports the structure 10 by the force generated by the support force generating member 126.

The bearing force generating member 126 may generate a greater force as the level of water stored in the pillar member 110 increases or the size of the space S decreases. It is preferable that the length or size of the bearing force generating member 126 is also changed according to the size of the space S, that is, the vertical length of the space S. For example, if the amount of water is increased or the water level is increased to decrease the length of the upper and lower portions of the space S, the length of the bearing force generating member 126 is reduced. As the length increases, the length of the bearing force generating member 126 increases. At this time, when the length of the bearing force generating member 126 is reduced or the length or size of the space S is smaller, the bearing force generating member 126 may generate a greater force.

The support force generating member 126 may be provided as a coil spring having a high rigidity to connect between the structure supporting plate 122 and the elevating member 124. In other words, the upper end of the supporting force generating member 126 is connected to the structure supporting plate 122 by a first protrusion 121 formed at the lower end of the supporting plate 122, and the lower end is connected to the upper end of the elevating member 124. It may be connected to the elevating member 124 by the formed second protrusion 123.

Here, the first protrusion 121 and the second protrusion 123 may be provided in the form of a circular column to be combined with the bearing force generating member 126. For reference, the shape or size of the first protrusion 121 and the second protrusion 123 may be changed according to the size or shape of the bearing force generating member 126.

Here, when water is introduced into the pillar body 110 and the water level of the pillar body 110 is increased, the elevating member 124 is raised in accordance with the water level. At this time, as the lifting member 124 rises, the support force generating member 126 in the form of a coil spring is reduced in compression or length, and when the support force generating member 126 is compressed or reduced in length, the elastic restoring force, that is, the elastic support force is the bearing force. It is generated in the generating member 126.

When the bearing force generating member 126 is compressed or reduced in length, the elastic force restoring force is generated because of the property of returning to the original length or state. This elastic restoring force acts in a direction opposite to the direction in which the bearing force generating member 126 is compressed. Therefore, the elastic restoring force of the bearing force generating member 126 acts downward and upward of the bearing force generating member 126.

However, since the lower end of the bearing force generating member 126 is supported by the elevating member 124 and the buoyancy of water, the elevating member 124 cannot move downward by the elastic restoring force. Since the upper end of the support force generating member 126 is supported by the structure support plate 122, the structure support plate 122 is pushed upward by the elastic restoring force, and as a result, the structure is supported by the support plate 122. The structure 10 being pushed upward by the elastic restoring force. That is, the elastic restoring force of the bearing force generating member 126 acts as an elastic bearing force for supporting the structure 10, so that the result of the bearing force generating member 126 supporting the load of the structure 10 can be obtained.

The support force generating member 126 increases the level of water so that the elevating member 124 rises and the size of the space S decreases, thereby pushing the structure support plate 122 by the elastic support force generated by compression. When the water level of the water is lowered and the elevating member 124 is lowered to increase the size of the space S, the compression may be released and loosened.

Therefore, when water flows into the column body 110 and the water level of the water stored in the column body 110 is increased, the elevating member 124 is raised to compress the bearing force generating member 126 so that the elastic restoring force or elastic bearing force is increased. In this case, the generated elastic support force pushes the structure support plate 122. As a result, the elastic support force formed by the elevating member 124 and the supporting force generating member 126 is a force for supporting the self-weight of the structure 10 in which the structure supporting plate 122 is located.

Furthermore, the force generated by the bearing force generating member 126 pushing the structure supporting plate 122 may be increased according to the size or shape of the bearing force generating member 126. In other words, when the size of the supporting force generating member 126 is increased or formed of a material having greater rigidity, the structure supporting plate 122 is increased by increasing the force of the supporting force generating member 126 that pushes the supporting plate 122. ) Can increase the bearing capacity.

However, when the support force generating member 126 is enlarged or the material is changed, the manufacturing cost of the support force generating member 126 as well as the manufacturing cost of the structure support pillar 100 itself may be increased, thereby reducing economic benefits. In addition, since the size of the pillar body 110 should also increase as the size of the bearing force generating member 126 increases, it may be inefficient.

Therefore, the size or material of the bearing force generating member 126 may be appropriately selected depending on the size or shape of the column body 110 as well as the size or shape of the structure 10 to be supported.

The force produced by the bearing force generating member 126, that is, the elastic restoring force or the elastic bearing force, may be adjusted according to the weight of the structure 10 or the magnitude of the load. For example, when the self-weight or load of the structure 10 is small and there is sufficient support force of a small size, the lifting member 124 may be lowered by lowering the water level. When it is necessary to support the structure 10 having a greater weight or load than this, the lifting member 124 may be raised by raising the water level slightly. If it is necessary to support the structure 10 of the greater weight or load than this, it is enough to raise the level so that the elevating member 124 in a higher position.

Knowing the load of the structure 10 to be supported, the rigidity of the column body 110, the rigidity of the bearing force generating member 126, or the spring constant, the bearing force generating member 126 is selected to support the structure 10. It is possible to determine whether to compress the degree, and accordingly adjust the water level of the water supplied to the inside of the pillar body (110).

However, when the state of supporting the structure 10 lasts for a long time, the water level may be reduced while the water stored inside the pillar body 110 naturally evaporates. When the water level is reduced, the force of the bearing force generating member 126 may be reduced. In this case, the force supporting the structure 10 is reduced so that the pillar body 110 may collapse or be damaged. Therefore, by periodically detecting the water level of the water stored in the pillar body 110 or the position (height) of the elevating member 124, if lower than the set water level or height, the water supply is further supplied to match the set water level or height There is a need. To this end, the support pillar 100 according to an embodiment of the present invention may further include a sensor (not shown) for detecting the water level or the height of the elevating member 124. The sensing value of the sensor may be transmitted to the controller.

On the other hand, the stopper 130 may be formed on the inner surface of the pillar body 110. The stopper 130 is a member for preventing the elevating member 124 that rises as the water level of rainwater or water introduced into the pillar body 110 is increased from the pillar body 110. That is, the stopper 130 is for limiting the maximum lift position of the elevating member 124.

As shown in Figures 1 to 4, the stopper 130 is provided in the interior of the pillar body 110, a shape protruding toward the inner direction of the pillar body 110, that is, the inner center of the pillar body 110 It can be formed as. Here, the stopper 130 is a portion in which the inner diameter of the pillar body 110 is relatively narrow, may be protruded toward the inner center of the pillar body 110, and only a portion of the pillar body 110 is radially inside the pillar body 110. It may be formed to protrude toward the center. That is, as long as the stopper 130 has a structure in which the elevating member 124 can be caught so that the elevating member 124 that rises together as the rainwater or water level stored inside the pillar body 110 rises no longer rises. It may be formed in any form.

For reference, the elevating member 124 is not protruded from the inside of the pillar body 110, but deformed in a shape such as a blocking bar, so that the elevating member 124 is securely caught by the stopper 130. You may.

That is, the size or shape of the stopper 130 is formed to a size that blocks the internal space of the column body 110, that is, the size smaller than the inner diameter of the column body 110 and the elevating member 124 is a stopper 130 It is preferable that it is formed to be caught, and may vary depending on the shape or size of the elevating member 124.

Meanwhile, referring to FIG. 4, a water inflow guide 132 may be provided at an upper end of the pillar body 110. In other words, the water inlet guide 132 may be provided at the upper end of the pillar body 110 to guide rainwater or water to flow into the pillar body 110.

The water inlet guide 132 is preferably formed in the form of a funnel (funnel). That is, the water inlet guide 132 may be formed in a shape in which the upper portion is wider and the lower portion is narrower than the upper portion.

Water is guided by the upper portion of the water inlet guide 132 toward the pillar body 110, and the water guided toward the pillar body 110 by the lower portion flows into the inside without outflowing to the outside of the pillar body 110. You can.

Here, when the water inlet guide 132 is formed on the upper portion of the pillar body 110, the structure support plate 122 may be provided on the upper side of the water inlet guide 132. In this case, the structure support plate 122 provided on the upper side of the water inlet guide 132 may be formed smaller than the size of the water inlet guide 132. Accordingly, a gap is formed between the edge of the structure support plate 122 and the water inlet guide 132, and rain or water may be introduced into the gap.

Hereinafter, referring to FIGS. 1 to 3, the operation principle of the pillar for supporting a structure 100 according to an embodiment of the present invention will be described.

First, the load or the weight of the structure 10 to be supported by the structure support pillar 100, the rigidity of the column body 110, the elastic force of the support force generating member 126 is calculated. From this it is possible to calculate the elastic force, that is, the force of the bearing force generating member 126 necessary for the support of the structure (10). Based on these results, the quantity or level of water to be introduced into the column body 110 may be determined. Accordingly, water flows into the pillar body 110. At this time, the incoming water may be rainwater or rain generated by the snow, the operator may be forced to the interior of the pillar body (110).

When water flows into the pillar body 110, the water level in the pillar body 110 is increased, and thus the elevating member 124 is raised along the inner surface of the pillar body 110. At this time, when the lifting member 124 is raised, the bearing force generating member 126 is compressed or reduced in length to generate elastic restoring force or elastic supporting force, and such force is applied to the structure supporting plate 122. As a result, the structure 10 is supported by the elastic bearing force of the bearing force generating member 126.

Here, when the amount of water introduced into the pillar body 110 is increased and the water level of the rainwater stored in the pillar body 110 is gradually increased, the elevating member 124 is caught by the stopper 130. In this case, when the elevating member 124 reaches up to the stopper 130 of the column body 110, the force of the bearing force generating member 126 is also increased to increase the force for pushing the structure supporting plate 122. .

Accordingly, the weight of the structure 10 in contact with the structure support plate 122 may be more effectively supported.

By the above configuration, the structure supporting pillar 100 according to an embodiment of the present invention may support the own weight of a structure having a weight such as a building, a bridge by storing water in the pillar. Furthermore, the structure support pillar 100 of the present invention can support only a small sized column when the weight of the structure to be supported is large, so that the cost of construction of the structure can be reduced. Accordingly, it is possible to save energy due to the material production according to the material cost of the structure.

In addition, the structure support pillar 100 of the present invention, by adjusting the amount of water stored in the column can adjust the magnitude of the force required to support the structure 10, if the structure is a building, such as expansion or reconstruction of the building It can easily cope with the change in its own weight due to remodeling or change of usage.

As described above, although one embodiment of the present invention has been described by specific matters such as specific components and limited embodiments and drawings, this is merely provided to help a more general understanding of the present invention. The present invention is not limited thereto, and various modifications and variations can be made by those skilled in the art to which the present invention pertains. Therefore, the spirit of the present invention should not be limited to the described embodiments, and all the things that are equivalent to or equivalent to the claims as well as the following claims will belong to the scope of the present invention.

10: Structure
100: pillar for structure support
110: pillar body
112: support block
120: support unit
121: first projection
122: structure support plate
123: second projection
124: lifting member
125: sealing member
126: bearing force generating member
130: stopper
140: water supply valve
150: water pump

Claims (10)

A pillar body provided inside the hollow; And
A support unit provided in the pillar body to support a structure located at an upper level according to the level of water introduced into the pillar body;
Structure support pillar comprising a.
The method of claim 1,
The support unit,
An elevating member provided inside the pillar body to be raised or lowered according to the water level flowing into or stored in the pillar body;
A structure support plate provided in the pillar body and in contact with the structure; And
And a support force generating member connected to the structure supporting plate and the elevating member and floating on water introduced into the pillar body to generate a force supporting the structure.
The method of claim 2,
The support force generating member is a structure supporting pillar, characterized in that for generating a force of a different size according to the size of the space formed between the lifting member and the structure support plate.
The method of claim 2,
The supporting force generating member, the structure supporting pillars, characterized in that to create a greater force as the lifting member rises.
The method according to claim 3 or 4,
The supporting force generating member is compressed or reduced in length when the lifting member is raised to push the structure support plate, when the lifting member is lowered structure support pillar, characterized in that the compression is released.
The method of claim 5,
The supporting force generating member is a structure supporting pillar, characterized in that provided by a compression coil spring.
The method of claim 5,
The pillar for supporting the structure, characterized in that the sealing member is provided on the outer circumferential surface or the circumferential surface of the elevating member.
The method of claim 7, wherein
A stopper is formed inside the pillar body,
The stopper is a structure supporting pillar provided at the highest position of the elevating member rising as the water level of the water flowing into the column body increases to stop the elevating member.
The method of claim 8,
The pillar for supporting the structure, characterized in that a sensor for detecting the height of the elevating member or the water level.
The method of claim 9,
And a water supply pump for additionally supplying water to the inside of the column body according to the sensing value of the sensor.

Images