KR101278586B1 - Intake tower renovation process of the work space - Google Patents

Abstract

PURPOSE: A method for securing the renovation space of an intake tower is provided to easily secure the renovation space of the intake tower by blocking the inflow of water through a water barrier structure to cover the lower side of the intake tower. CONSTITUTION: A method for securing the renovation space of an intake tower comprises the following steps: flattening the surrounding ground(7) of the lower side of an intake tower(5) installed under the ground; settling a ring-shaped base frame(10) in the flattened ground; injecting concrete into the base frame and curing the concrete; pressurizing a water barrier structure(20) through a cylinder(60) on the upper side of the intake tower for settling in the upper side of the base frame; and discharging water between the water barrier structure and the intake tower to the outside.

Description

INTAKE TOWER RENOVATION PROCESS OF THE WORK SPACE}

The present invention wraps the lower side of the intake tower in the upper part of the annular base frame seated on the ground around the lower side of the intake tower construction of the annular water barrier structure in a simpler and faster time between the annular water barrier structure and the intake tower It is possible to more easily secure a work space for repairing cracks, etc. generated in the water intake tower, and the inflow of water from the outside of the annular water barrier structure to the inside of the annular water barrier structure through the watertight portion and the secondary watertight portion. It can be blocked with a higher efficiency, and relates to a method for securing a work space of the renovation of the intake tower with excellent water tightness.

Water is an indispensable resource for the survival of all living things by humans.

As a result of the increase in population and industrialization, various water resources were required in large quantities. Accordingly, in order to supply water to the required areas, water intake towers are being constructed to collect water from rivers and lakes.

However, if time has elapsed and it is damaged due to cracks in the water intake tower installed in the river or lake, it is not possible to secure a work space for repairing cracks in the water tower. There is a problem that the renovation work is not good.

The present invention was created in order to solve the above-described problems, and the annular water barrier structure on the upper part of the annular base frame seated on the ground around the lower side of the intake tower in a state wrapped around the intake tower in a more convenient and faster time. It is possible to more easily secure a work space for repairing cracks generated in the water intake tower between the annular water barrier structure and the water intake tower by constructing a construction, and also the outer side of the annular water insulation structure through a watertight portion and an auxiliary watertight portion. It is an object of the present invention to provide a method for securing a work space of the water tower renovation with excellent watertightness can block the inflow of water into the inner structure of the annular structure at a higher efficiency.

The present invention for achieving the above object comprises the steps of: a) planarizing the ground around the lower side of the intake tower installed in water; b) mounting an annular base frame on the flattened ground around the lower side of the intake tower with the lower side of the intake tower wrapped; and c) mounting an annular water barrier structure on top of the base frame of the annular shape.

Here, the annular base frame of step b) is an annular caisson plant seated on the flattened ground around the lower side of the intake tower in a state wrapped around the lower side of the intake tower; It is preferable that the guide tube is formed vertically at a predetermined interval on the upper portion of the caisson plant of the annular so as to communicate with the interior of the caisson plant of the annular to guide concrete into the caisson plant of the annular.

And, the b) the annular reinforcing beam inside the annular caisson plant in step b) is preferably provided.

In addition, an annular support portion is formed on the upper portion of the annular base frame of step b) to support the lower side of the annular water film structure, and the annular support portion is formed on the upper portion of the base frame, An annular lower support member in which an annular lower groove recessed in a lower direction of the base frame and an annular lower protruding member projecting in an upper direction of the base frame are alternately formed at regular intervals; An annular upper groove of the annular upper support of the base frame is separably mounted on the upper portion of the lower support member, the lower side of the water barrier structure is seated in the upper side, and recessed in the upper direction of the base frame. It is preferable that the annular upper protrusion member protruding in the lower direction is formed in the upper support member of the annular formed alternately at a predetermined interval.

Furthermore, it is preferable that an annular watertight portion is provided in the annular lower groove and the annular upper groove, respectively.

In addition, an annular auxiliary watertight portion is provided on the outer circumferential surface of the annular upper support member, and the auxiliary watertight portion is an annular plate formed on the outer circumferential surface of the upper support member of the annular shape; It is preferably configured to include; an annular auxiliary watertight member formed below the annular plate and in contact with the outer peripheral surface of the annular lower support member.

In addition, d) pressing the annular water film structure in the annular base frame direction through the cylinder provided on the top of the water intake tower so that the annular water film is located in the upper direction of the structure.

In addition, it is preferable that a cover is provided in the upper side of the annular water barrier structure is accommodated therein under the cylinder of step d).

And, between the step b) and the step c) it is preferable that the step of curing by injecting concrete into the interior of the base frame of the b ₁ ) annular.

Also, e) discharging water between the annular water barrier structure and the water intake tower to the outside of the annular water barrier structure.

The present invention wraps the lower side of the intake tower in the upper part of the annular base frame seated on the ground around the lower side of the intake tower construction of the annular water barrier structure in a simpler and faster time between the annular water barrier structure and the intake tower It is possible to more easily secure a work space for repairing cracks, etc. generated in the water intake tower, and the inflow of water from the outside of the annular water barrier structure to the inside of the annular water barrier structure through the watertight portion and the secondary watertight portion. Can be blocked at a higher efficiency, so the watertightness is very excellent.

1 is a cross-sectional view schematically showing a state in which the annular base frame used in the work space securing method of the intake tower renovation of the present invention seated on the ground around the bottom of the intake tower,
2 is a cross-sectional view schematically illustrating a state in which an annular water barrier structure is seated on an upper portion of an annular base frame;
Figure 3 is a partially enlarged cross-sectional view schematically showing the annular support,
4 is a partially enlarged cross-sectional view of FIG.
5 is a sectional view schematically showing a state in which the cylinder presses the annular water blocking structure in the direction of the annular base frame;
6 is a partially enlarged front view of an enlarged cylinder,
7 is a sectional view schematically showing a state in which concrete is injected into the annular base frame;
8 is a cross-sectional view schematically illustrating a state in which water between the annular water barrier structure and the water intake tower is discharged to the outside of the annular water barrier structure;
9 is a cross-sectional view schematically showing a state in which a work space is formed between the annular water barrier structure and the water intake tower.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

The work space securing method of the renovation of the intake tower, which is an embodiment of the present invention, is largely referred to as a) ground leveling step (hereinafter referred to as' a) 'step, and b) foundation frame mounting step (hereinafter referred to as' b) step.) And a water barrier structure seating step (hereinafter referred to as 'c) step').

1 is a cross-sectional view schematically showing a state in which the annular base frame 10 used in the work space securing method of the intake tower renovation of the present invention is mounted on the ground 7 around the bottom of the intake tower 5.

First, the step a) is to flatten the ground 7 around the lower side of the water intake tower 5 installed or newly installed in the water such as a river or a lake in a horizontal state.

As an example, an operator including a diver may flatten the ground 7 around the bottom of the water intake tower 5 in a horizontal state by using a flattening work tool including a shovel or the like.

Next, the step b) is an annular base frame 10 in the flattened ground 7 in a horizontal state around the lower side of the intake tower 5 in a state of wrapping the lower side of the intake tower 5 as shown in FIG. ) To settle down.

The base frame 10 of the annular shape may be seated on the flattened ground 7 in a horizontal state around the lower side of the intake tower 5 in a state in which the lower side of the intake tower 5 is wrapped with heavy equipment including a crane or the like. .

2 is a cross-sectional view schematically illustrating a state in which the annular water barrier structure 20 is seated on the upper portion of the annular base frame 10.

Next, step c) is a step of seating the annular water barrier structure 20 on top of the annular base frame 10 as shown in FIG.

The annular cladding structure 20 may also be mounted vertically on top of the annular base frame 10 through heavy equipment including a crane or the like.

The annular water barrier structure 20 may be composed of a grating beam 210 and a partition wall 220.

The lattice beam 210 may be vertically seated on an upper portion of the annular base frame 10.

The cross-sectional shape of the grating beam 210 may be formed in the 'H' shape or the like.

The partition wall 220 may be integrally formed on the outer circumferential surface of the grating beam 210 in a state in which the outer circumferential surface of the grating beam 210 is wrapped.

Next, the annular base frame 10 of step b) may be composed of an annular caisson plant 110 and a guide tube 120.

The caisson plant 110 of the annular shape may be horizontally seated on the flattened ground 7 around the lower side of the intake tower 5 in a state in which the lower portion of the intake tower 5 is wrapped.

The guide tube 120 may be vertically formed at a predetermined interval on the upper portion of the annular caisson plant 110 so as to communicate with the inside of the annular caisson plant 110.

The guide tube 120 guides the concrete 9 into the caisson plant 110 in an annular shape.

Various types may be used as the concrete 9, but it is particularly preferable to use underwater concrete that hardens without falling in strength even in water.

Next, in order to improve durability of the annular caisson plant 110 in step b), an annular reinforcement beam having an annular reinforcement beam having a cross-sectional shape may be formed in an 'H' shape. 130 of FIG. 7 may be provided.

3 is a partially enlarged cross-sectional view schematically showing the annular support 30, and FIG. 4 is a partially enlarged cross-sectional view of FIG.

Next, as shown in FIGS. 3 and 4, the guide tube 120 is maintained at a predetermined interval on an upper portion of the annular caisson plant 110 of the annular base frame 10 of step b). The annular support portion 30 may be formed outside the guide tube 120 so as to support the lower side of the annular water barrier structure 20.

The annular support part 30 may be formed of an annular lower support member 310 and an annular upper support member 320.

The lower support member 310 of the annular shape may be integrally formed on the upper portion of the annular caisson plant 110 of the base frame 10 of the annular shape.

An upper groove of the annular lower support member 310 may be alternately formed with an annular lower groove 311 and an annular lower protrusion member 312 at regular intervals.

The annular lower groove 311 may be recessed to a predetermined depth in the lower direction of the annular caisson plant 110 of the annular base frame 10.

The annular lower protrusion member 312 may protrude in an upper direction of the annular caisson plant 110 of the annular base frame 10.

The upper support member 320 of the annular may be detachably mounted on the upper portion of the lower support member 310 of the annular.

The lower side of the water barrier structure 20 may be seated inside the upper side of the upper support member 320 of the annular shape.

In the lower side of the upper support member 320 of the annular upper annular groove 321 and the annular upper protrusion member 322 may be formed alternately at a predetermined interval.

The upper groove 321 of the annular shape may be recessed to a predetermined depth in the upper direction of the annular caisson plant 110 of the base frame 10.

The annular upper protrusion member 322 may protrude in a downward direction of the annular caisson plant 110 of the base frame 10 to be engaged with the annular lower protrusion member 312.

In order to block the inflow of water in the inward direction of the annular water blocking structure 20 from the outer side of the annular water blocking structure 20,

As shown in FIG. 3, an annular watertight portion 40 may be formed in an annular lower ring 311 and an annular upper upper groove 321.

When the annular upper support member 320 is seated on an upper portion of the annular lower support member 310, the annular lower protrusion member 312 and the annular upper protrusion member 322 are each annular and watertight. The watertight part 40 is compressed in contact with the part 40.

In order to block the inflow of water from the outer side of the annular water barrier structure 20 to the inner side of the annular water vessel structure 20 with higher efficiency, the annular auxiliary watertight portion 50 as shown in FIG. 3. May be further provided.

The annular subtight portion 50 may be configured to include an annular plate 510 and an annular subtight member 520.

The annular plate 510 may include an annular inner plate 511 and an annular outer plate 512.

The annular inner plate 511 may be integrally formed on the outer circumferential surface of the annular upper support member 320 in a state in which the outer circumferential surface of the annular upper support member 320 is wrapped.

The annular outer plate 512 may be integrally formed on the outer circumferential surface of the annular inner plate 511 while covering the outer circumferential surface of the annular inner plate 511.

The vertical length of the annular outer plate 512 may be longer than the vertical length of the annular inner plate 511.

The secondary watertight member 520 of the annular shape may be formed in a 'Y' shape or the like and may be made of a rubber material or the like.

The annular auxiliary watertight member 520 may be composed of an annular upper auxiliary watertight member 521 and an annular lower auxiliary watertight member 522.

The annular upper secondary sealing member 521 may be integrally formed on the lower side of the annular outer plate 512 in a state in which the outer peripheral surface of the annular outer plate 512 of the annular plate 510 is wrapped. .

The annular subsidiary sealing member 522 may be composed of an annular first subsidiary sealing member 522a and an annular second subsidiary sealing member 522b.

The annular first lower secondary sealing member 522a may be formed integrally with the lower side of the upper secondary sealing member 521.

The annular second lower secondary watertight member 522b may be integrally formed on an inner circumferential surface of the annular first lower secondary watertight member 522a.

So that the lower side of the annular second lower secondary sealing member 522b is in contact with the lower outer peripheral surface of the annular lower support member 310,

The annular second lower secondary watertight member 522b may be inclined downward toward the lower outer peripheral surface of the annular lower support member 310 as it goes from the upper side to the lower side.

5 is a cross-sectional view schematically illustrating a state in which the cylinder 60 presses the annular water blocking structure 20 in the direction of the annular base frame 10, and FIG. 6 is a partially enlarged front view in which the cylinder 60 is enlarged.

Next, the method for securing a working space of the inventors of the intake tower renovation may be made further comprising a step of pressing the water barrier structure (hereinafter 'd) step').

In step d), as shown in FIG. Pressing in the direction of the annular base frame 10.

As the length of the rod 610 of the cylinder 60 is extended in the vertical direction, the annular water blocking structure 20 is pressed upwards of the annular caisson plant 110 of the annular base frame 10. It becomes possible.

A connection part 80 may be further provided between the cylinder 60 and the upper portion of the water intake tower 5 to connect the upper portion of the cylinder 60 and the water intake tower 5.

The connection part 80 may be composed of a connection plate 810, an upper connection member 810, and a lower connection member 820.

The connecting plate 810 may be detachably bolted to the upper outer peripheral surface of the water intake tower 5 at a predetermined interval.

The upper connecting member 810 may be made of an upper connecting rod, etc., whose cross-sectional shape may be formed in a circular shape or the like.

The upper connecting member 810 may be integrally formed horizontally between the upper side of the cylinder 60 and the upper side of the connecting plate 810.

The lower connection member 820 may be formed of a lower connection rod, etc., in which the cross-sectional shape may be formed in a circular shape or the like.

The lower connection member 820 may be integrally formed horizontally between the lower side of the cylinder 60 and the lower side of the connecting plate 810 to be located in the lower direction of the upper connecting member 810.

Next, in order to allow the cylinder 60 to pressurize the annular cladding structure 20 more stably in an upward direction of the annular caisson plant 110 of the annular base frame 10.

As shown in FIG. 6, a cover 70 may be provided at a lower side of the rod 610 of the cylinder 60 in step d) to accommodate the upper side of the annular water barrier structure 20 therein.

The cover 70 may include a horizontal plate 710, one vertical bulkhead 720 and the other vertical bulkhead 730.

The horizontal plate 710 may be integrally formed under the rod 610 of the cylinder 60.

The one side vertical bulkhead 720 and the other vertical bulkhead 730 may be integrally formed on one side of the horizontal plate 710 and the other side of the horizontal plate 720, respectively.

An upper side of the annular water barrier structure 20 may be accommodated between the one side vertical bulkhead 720 and the other vertical bulkhead 730.

7 is a cross-sectional view schematically showing a state in which the concrete 9 is injected into the annular base frame 10.

Next, in order to more stably seat the annular water barrier structure 20 on the annular caisson plant 110 of the annular base frame 10, the steps b) and c) B ₁ ) concrete injection step (hereinafter referred to as 'b ₁ ) step') may be further provided.

Step b ₁ ) is the step of curing by injecting concrete 9 into the interior of the annular caisson plant 110 of the annular base frame 10 through the guide tube 120 as shown in FIG. to be.

8 is a cross-sectional view schematically illustrating a state in which water between the annular water blocking structure 20 and the water intake tower 5 is discharged to the outside of the annular water blocking structure 20.

Next, the method for securing a working space of the inventors of the intake tower renovation may further comprise e) water discharge step (hereinafter referred to as' e) step.)

The step e) is a step of discharging water between the annular water barrier structure 20 and the water intake tower 5 to the outside of the annular water barrier structure 20 through the pump 90 as shown in FIG. .

The pump 90 may be detachably bolted to the upper side of the annular water barrier structure 30.

A suction pipe 910 extending in the direction of the upper surface of the annular caisson plant 110 of the annular base frame 10 may be connected to the suction port of the pump 90.

An outlet pipe 920 extending in an outward direction of the annular water barrier structure 30 may be connected to the outlet of the pump 90.

The water between the annular water blocking structure 20 and the water intake tower 5 is sucked into the suction pipe 910 by the pump 90 and then through the discharge pipe 920 of the annular water blocking structure 20. It can be discharged outward.

9 is a cross-sectional view schematically showing a state in which the work space S is formed between the annular water barrier structure 20 and the water intake tower 5.

The present invention configured as described above has the annular water barrier in the upper part of the base frame 10 of the annular seated on the ground 7 around the lower side of the intake tower 5 in a state wrapped around the lower side of the intake tower 5. Construction of the structure 20 in a simpler and faster time to repair the cracks generated in the water intake tower 5 between the annular water barrier structure 20 and the water intake tower 5 as shown in FIG. Not only can the work space (S) be more easily secured, but the water barrier structure 20 of the annular through the watertight portion 40 and the secondary watertight portion 50 outside the annular water barrier structure 20 inside the annular water barrier structure 20. The inflow of water to the direction can be blocked with higher efficiency, there is an advantage that the water tightness is very excellent.

10; Annular base frame, 20; Annular cladding structure.

Claims (10)

a) planarizing the ground 7 around the lower side of the water intake tower 5 installed in the water;
b) mounting an annular base frame (10) in the flattened ground (7) around the lower side of the intake tower (5) while wrapping the lower side of the intake tower (5);
c) mounting an annular water barrier structure 20 on top of the annular base frame 10;
An annular support portion 30 is formed on the upper part of the annular base frame 10 of step b) to support the lower side of the annular water barrier structure 20.
The annular support part 30 is formed on an upper portion of the base frame 10, and has an annular lower groove 311 recessed in a lower direction of the base frame 10 in an upper side thereof, and the base frame 10. An annular lower support member 310 protruding in an upper direction of the annular lower protruding member 312 formed at an interval;
An annular detachable seated on the upper side of the lower support member 310 of the annular, the lower side of the water barrier structure 20 is seated in the upper side, the annular recessed in the upper direction of the base frame 10 in the lower side The upper groove 321 of the, and the upper projection member 322 of the annular protruding in the lower direction of the base frame 10 is an annular upper support member 320 is formed alternately at a predetermined interval; Work space securing method of water intake tower renovation.
The method of claim 1,
The annular base frame 10 of step b) is an annular caisson plant 110 seated on the flattened ground 7 around the lower side of the intake tower 5 in a state of wrapping the lower side of the intake tower 5. Wow;
Vertically formed at a predetermined interval on the upper portion of the annular caisson plant 110 so as to communicate with the interior of the annular caisson plant 110 to guide the concrete (9) inside the annular caisson plant (110) Guide pipe (120); the work space securing method of the intake tower renovation, characterized in that consisting of.
The method of claim 2,
The b) reinforcing beam 130 of the annular caisson plant 110 in the annular step of step;
The method of claim 1,
Method of securing a work space of the intake tower renovation, characterized in that the annular watertight portion (40) is provided in the annular lower groove (311) and the annular upper groove (321), respectively.
The method of claim 1,
An annular auxiliary watertight part 50 is provided on the outer circumferential surface of the annular upper support member 320,
The auxiliary watertight part 50 includes an annular plate 510 formed on an outer circumferential surface of the upper support member 320 of an annular shape;
The annular auxiliary watertight member 520 formed on the lower side of the annular plate 510 and in contact with the outer circumferential surface of the lower support member 310 of the annular; .
The method of claim 1,
d) The annular water barrier structure 20 is positioned in the direction of the annular base frame 10 through a cylinder 60 provided on the top of the water intake tower 5 so that the annular water barrier structure is positioned in an upper direction of the annular structure 20. Method of securing a workspace of the intake tower renovation, characterized in that it comprises a step of pressing.
The method according to claim 6,
The lower part of the cylinder (60) of the step d) the upper surface of the annular water barrier structure 20 is provided with a cover 70 is accommodated therein, characterized in that the intake tower refurbishment work space securing method.
The method of claim 1,
Between b) and c) step b ₁ ) the method of securing a working space of the intake tower renovation, characterized in that it further comprises the step of curing by injecting concrete 9 into the interior of the base frame 10 of the annular shape .
7. The method according to claim 1 or 6,
e) discharging water between the annular water blocking structure 20 and the water intake tower 5 to the outside of the annular water blocking structure 20; . delete

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