KR102641291B1 - Stainless cylindrical water tank fixing device with seismic function and construction method - Google Patents

Abstract

The present invention secures a seismic stopper to the unit panel forming the outer shape of a cylindrical water tank and the upper surface of the concrete foundation, thereby forming a binding force in the event of vibration due to an earthquake, preventing excessive separation and fall, and forming first and second stoppers on the outer peripheral surface of the exterior material. By winding the binding band and fixing it by inserting it into the first and second binding holes formed on the earthquake-resistant stopper, it effectively supports the lateral pressure concentrated at the bottom of the cylindrical water tank, preventing expansion of the cylindrical water tank and damage to the insulation and exterior materials. It relates to a lower fixing device and construction method for a stainless steel cylindrical water tank.

Description

Bottom fixing device and construction method of a stainless steel cylindrical water tank with seismic function {Stainless cylindrical water tank fixing device with seismic function and construction method}

The present invention relates to a lower fixing device and construction method for a stainless steel cylindrical water tank with an earthquake-resistant function. More specifically, the present invention relates to a device for fixing the bottom of a stainless steel cylindrical water tank and a construction method. More specifically, the present invention relates to the vibration caused by an earthquake by fixing a seismic stopper to the unit panel part forming the outer shape of the cylindrical water tank and the upper surface of the concrete foundation. When this occurs, a binding force is formed to prevent excessive separation and overturning. The first and second binding bands are wound around the outer peripheral surface of the exterior material and fixed by inserting them into the first and second binding holes formed in the earthquake-resistant stopper, respectively, so that the water concentrated at the bottom of the cylindrical water tank is fixed. It relates to a lower fixing device and construction method for a stainless steel cylindrical water tank with an earthquake-resistant function that can effectively support lateral pressure to prevent expansion of the cylindrical water tank and damage to the insulation and exterior materials.

In general, a cylindrical water tank is intended to store water used for domestic purposes and drinking water. It is manufactured by continuously fixing circular unit panels to the upper part of the foundation, and can store water inside and keep it in a clean state.

This cylindrical water tank has been registered as Utility Model No. 20-0348734, a cylindrical storage tank with a curved vertical extension panel combination structure (hereinafter referred to as 'Prior Document 1').

The prior art document 1 is a cylindrical storage tank with a curved vertical extension panel combined structure in which the lower part of the main body frame is sealed with a circular bottom plate and the upper part of the main body frame is sealed with a cover, which is fixed to the edge of the bottom plate. a lower fixture that is curved to have a ring shape and has a predetermined cross-sectional shape to simultaneously serve as a support jaw and a reinforcement; It is curved to maintain watertightness at the corners of the lower fixture and the bottom plate, and includes a plurality of vertical extension panels with left and right flange sides integrally bent on the left and right sides.

However, in the case where the bottom of the cylindrical storage tank where water is stored is fixedly installed on the concrete floor as in the preceding document 1, when an earthquake due to changes in the earth's crust or vibration occurs due to nearby construction, the water is directly connected to the storage tank from the concrete floor. There is a problem in that the shape of the storage tank is deformed or the piping such as the inlet and outlet is damaged due to vibration being transmitted to the storage tank, causing the storage tank to lose its function.

Recently, in order to solve the above problems, a water tank with an earthquake-resistant structure (hereinafter referred to as 'Prior Document 2') has been registered under Patent No. 10-1796510.

The prior art document 2 includes a break-wave type flow wall that divides the internal space of a cylindrical water tank into a plurality of water storage spaces and enables the movement of stored water in each water storage space; A floating fixture configured between the bottom of the water tank and the concrete bottom to ensure that the water tank can flow a predetermined distance in the left and right directions when vibration occurs in the left and right directions and is fixed to the concrete floor; and an expansion pipe that is configured between the pipe inside the water tank and the pipe outside the water tank to absorb vibration when it occurs.

However, in the prior art document 2, in order to provide a seismic isolation function to a cylindrical water tank, a 'ㄷ' shaped support frame and stopper were installed to provide a seismic isolation function by floating it from the floor, thereby increasing the manufacturing cost and labor costs, making it uneconomical.

In addition, since the lower part of the water tank is fixed by a flow fixture, not only is the lower structure of the water tank vulnerable, but there is a risk that the first water tank will expand and deform due to the lateral pressure concentrated in the lower part of the water tank.

In addition, there was a problem in that the insulation and finishing jacket were damaged due to the lateral pressure applied to the first and second water storage tanks, resulting in loss of insulation function.

Republic of Korea Utility Model No. 20-0348734 (announced on April 30, 2004) Republic of Korea Patent No. 10-1796510 (announced on November 10, 2017)

The present invention was created to solve the above problems. The purpose of the present invention is to secure a seismic stopper to the unit panel part forming the outer shape of a cylindrical water tank and the upper surface of the concrete foundation, thereby forming a binding force in the event of vibration due to an earthquake, thereby creating an excessive The purpose is to provide a lower fixing device and construction method for a stainless steel cylindrical water tank with an earthquake-resistant function that can prevent separation and overturning.

In addition, another object of the present invention is to effectively support the lateral pressure concentrated at the bottom of the cylindrical water tank by wrapping the first and second binding bands around the outer peripheral surface of the exterior material and fixing them into the first and second binding holes formed in the earthquake-resistant stopper, respectively. The purpose is to provide a lower fixing device and construction method for a stainless steel cylindrical water tank with an earthquake-resistant function that prevents expansion of the tank and damage to the insulation and exterior materials.

The object of the present invention is not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above problems, the lower fixing device of a stainless steel cylindrical water tank with an earthquake-resistant function includes: a flooring material formed on the upper surface of a concrete foundation to form the bottom surface of the cylindrical water tank; A unit panel portion in which a first unit panel is continuously fixed vertically along an edge of the flooring material, and a second unit panel is continuously fixed on an upper part of the first unit panel to form an external shape of a cylindrical water tank; It is located at four locations divided at 90° on the outside of the unit panel, and accommodates the lower rib of the first unit panel and a reinforcing rib formed by fixing the upper rib of the first unit panel and the lower rib of the second unit panel. A seismic stopper that forms a binding force when vibration occurs due to an earthquake; an insulating material inserted between the lower ribs and the upper ribs of the first and second unit panels; An exterior material covering the outside of the insulation material and extending from the top of the unit panel to the bottom; It is characterized by including a binding band portion that is respectively coupled to the first and second binding holes formed in the earthquake-resistant stopper and is wrapped around the outer peripheral surface of the exterior material to provide resistance to lateral pressure generated by an earthquake.

The unit panel unit includes a first unit panel fixed to an upper edge of the flooring material and welded to the flooring material; a second unit panel fixed to an upper part of the first unit panel; It includes a reinforcing rib formed at a contact portion between an upper portion of the first unit panel and a lower portion of the second unit panel, wherein the first and second unit panels include a lower rib formed at a lower end portion; an upper rib formed at the upper end; a vertical plate vertically connected to ends of the lower rib and the upper rib; Two rows of reinforcing grooves are formed at regular height intervals on the vertical plate, and the reinforcing ribs are formed by welding the ground portions of the upper rib of the first unit panel and the lower rib of the second unit panel.

The earthquake-resistant stopper includes a lower support plate fixed to the concrete foundation and on which a plurality of anchor holes are formed; A central reinforcement plate formed perpendicular to the upper center of the lower support plate; Anchor bolts embedded in the concrete foundation to secure the lower support plate to the concrete foundation; a first connection hole formed in the lower part of the central reinforcement plate adjacent to the lower support plate into which the first connection band is inserted; a second connection hole formed on the upper part of the central reinforcement plate into which the second connection band is inserted; It includes a rib guide groove formed in the central reinforcement plate on the upper part of the second fastening hole to be open toward the unit panel portion.

It further includes a vertical support plate formed vertically at an end of the central reinforcement plate and in close contact with the outer peripheral surface of the unit panel portion.

It further includes an upper support plate formed perpendicular to an end of the central reinforcement plate above the rib guide groove and in close contact with the outer peripheral surface of the second unit panel of the unit panel portion.

The first and second fastening holes are formed at an end of the central reinforcement plate adjacent to the unit panel portion, spaced apart from each other by a thickness including the insulation material and the exterior material.

The binding band portion includes a first binding band inserted into the first binding hole of the earthquake-resistant stopper and wound around the outer peripheral surface of the exterior material; It includes a second connection band that is inserted into the second connection hole of the earthquake-resistant stopper and wound around the outer peripheral surface of the exterior material, wherein the first and second connection bands are cut longer than the circumference of the exterior material, and are fastened to the ends of the first and second connection bands. The member is fixed and fastened by pulling the fastening member while the first and second fastening bands are wound around the outer peripheral surface of the exterior material, respectively.

The height of the first connection band is formed to be higher than the height of the second connection band to support the lateral pressure transmitted to the bottom of the cylindrical water tank and prevent damage to the welded portion of the cylindrical water tank.

In addition, the method of constructing a lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention involves cutting a stainless steel plate on the upper surface of the concrete foundation with a laser and seating it to match the bottom specifications of the cylindrical water tank, followed by welding. Bonding to form a flooring material; After setting the lower rib of the first unit panel vertically so that it is the same as the outer shape of the flooring, the step of fixing the ground part where the flooring material and the lower rib meet by welding is repeated to form the outer shape of the lower part of the water tank, and to the upper rib of the first unit panel. After seating the lower ribs of the second unit panel so that they overlap, repeating the step of fixing the ground portions of the upper rib and the lower rib by welding to fix the unit panel portion to form the outer shape of the upper part of the water tank; Seating the lower support plate on four concrete foundations divided at 90° on the outside of the unit panel section, and fixing the earthquake-resistant stopper by fastening nuts to anchor bolts while keeping the vertical support plate in close contact with the outer peripheral surface of the unit panel section; Installing a thermal insulation material in the space formed between the lower rib and the upper rib of the first and second unit panels; Wrapping an exterior material having a vertical wave shape around the outer peripheral surface of the insulation material and fixing the insulation material so that it is not exposed to the outside; The first binding band is inserted into the first binding hole formed at the bottom of the earthquake-resistant stopper, and the outer peripheral surface of the exterior material is wound one turn and fixed through the fastening member. The second binding band is inserted into the second binding hole formed at the top of the earthquake-resistant stopper, and the first binding band is inserted into the second binding hole formed at the top of the earthquake-resistant stopper. It is characterized by including the step of fixing in the same way as the binding band.

According to the present invention, by fixing the seismic stopper to the unit panel part forming the outer shape of the cylindrical water tank and the upper surface of the concrete foundation, a binding force is formed when vibration due to an earthquake occurs, which has the advantage of preventing excessive separation and overturning.

In addition, according to the present invention, the first and second binding bands are wound around the outer peripheral surface of the exterior material and fixed by inserting them into the first and second binding holes formed in the earthquake-resistant stopper, respectively, thereby effectively supporting the lateral pressure concentrated in the lower part of the water tank and maintaining the cylindrical water tank. It has the advantage of preventing expansion and damage to insulation and exterior materials.

Figure 1 is an overall configuration diagram of a water tank to which a lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention is applied.
Figure 2 is a perspective view of a lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention.
Figure 3 is a perspective view of the unit panel portion according to the present invention.
Figure 4 is a perspective view of a seismic stopper according to the present invention.
Figure 5 is a cross-sectional view of the lower fixing device of a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention.
Figure 6 is an enlarged view of part 'B' of Figure 5.
Figure 7 is a process diagram for the construction of a lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. First, when adding reference numerals to components in each drawing, it should be noted that identical components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted. In addition, preferred embodiments of the present invention will be described below, but of course, the technical idea of the present invention is not limited or limited thereto and can be practiced by those skilled in the art.

First, Figure 1 is an overall configuration diagram of a water tank to which the lower fixing device of a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention is applied, and Figure 2 is a lower fixing device of a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention. This is a perspective view of

The lower fixing device (A) of the stainless steel cylindrical water tank with earthquake-resistant function according to the present invention includes flooring 100, unit panel portion 200, earthquake-resistant stopper 300, insulation material 400, exterior material 500, and binding. Includes a band portion 600.

The flooring material 100 is formed of a stainless steel plate, is seated on the upper surface of the concrete foundation (C) to match the floor specifications of the cylindrical water tank, and is fixed through overlap welding.

The unit panel portion 200 is fixed vertically to form a cylindrical shape along the edge of the flooring material 100 to form the external shape of a water tank.

As shown in FIG. 3, the unit panel portion 200 includes a first unit panel 210, a second unit panel 220, and a reinforcing rib 230.

The first unit panel 210 is continuously erected vertically above the edge of the flooring 100 to form a cylindrical shape, and the inside of the first unit panel 210 and the ground portion of the flooring 100 are fixed by welding. become integrated.

The second unit panel 220 is seated on the top of the first unit panel 210 and the ground portion is fixed by welding to integrate the first and second unit panels 210 and 220.

Here, the first and second unit panels 210 and 220 are manufactured with a curved surface to form the external shape of a cylindrical water tank, and the radius of the curved surface may vary depending on the diameter of the cylindrical water tank.

The first unit panels 210 and 220 have horizontally bent lower ribs 211 and 221 formed at the lower ends, and horizontally bent upper ribs spaced apart from the lower ribs 211 and 221 at a certain height ( 212)(222) is formed.

The width of the lower ribs 211 (221) and the upper ribs 212 and 222 is 25 mm, and the width may increase depending on the diameter of the water tank.

Vertical plates 213 and 223 are formed at the ends of the lower ribs 211 and 221 and the upper ribs 212 and 222 to form the wall of the cylindrical water tank.

Reinforcement grooves 214 and 224 are formed at regular height intervals on the vertical plates 213 and 223, and the reinforcement grooves 214 and 224 protrude in a semicircular shape to increase rigidity.

The reinforcement grooves 214 and 224 may be formed in at least one row, and are preferably formed in two rows.

In addition, the reinforcing rib 230 protrudes outward from the contact portion of the upper part of the first unit panel 210 and the lower part of the second unit panel 220.

The reinforcing rib 230 is formed by welding a ground portion where the upper rib 212 of the first unit panel 210 and the lower rib 221 of the second unit panel 220 are in contact.

Meanwhile, the earthquake-resistant stopper 300 is installed at four locations divided at 90° on the outside of the unit panel unit 200 and prevents damage to the cylindrical water tank by supporting the unit panel unit 200 and forming a binding force when vibration occurs. .

Here, the number of seismic stoppers 300 installed can increase as the size of the cylindrical water tank increases.

As shown in FIG. 4, the earthquake-resistant stopper 300 includes a lower support plate 310, a central reinforcement plate 320, an anchor bolt 330, a first attachment hole 340, a second attachment hole 350, Includes a rib guide groove (360).

The lower support plate 310 is seated and fixed on the upper part of the concrete foundation (C), and a plurality of anchor holes 311 are formed in the lower support plate 310, and two anchor holes 311 are formed at the inner end adjacent to the unit panel portion 200. An anchor hole 311 is formed, and one anchor hole 311 is formed at the outer end of the unit panel portion 200 toward the other side.

The central reinforcement plate 320 is formed vertically at the upper center of the lower support plate 310 and is in close contact with the outer peripheral surface of the unit panel portion 200.

The central reinforcement plate 320 is formed to be narrow at the top and wider toward the outside in order to stably withstand the lateral pressure applied to the unit panel portion 200.

The anchor bolt 330 is embedded in the concrete foundation (C) and the upper end protrudes at a certain height, and the end of the anchor bolt 330 is coupled to the anchor hole 311 formed in the lower support plate 310 through a nut. It is fixed.

The lower support plate 310 and the central reinforcing plate 320 are formed integrally, the lower supporting plate 310 is fixed to the concrete foundation (C), and the central reinforcing plate 320 is attached to the outer peripheral surface of the unit panel portion 200. Because it is fixed, the slushing phenomenon generated by earthquakes can be minimized and lateral pressure can be stably supported.

The first attachment hole 340 is formed vertically through the lower part of the central reinforcement plate 320 adjacent to the lower support plate 310, into which the first attachment band 610 is inserted.

The second fastening hole 350 is formed vertically through the upper part of the central reinforcement plate 320 into which the second fastening band 620 is inserted.

Here, the first and second fastening holes 340 and 350 are formed at the end of the central reinforcement plate 320 adjacent to the unit panel portion 200 and spaced outward by the thickness including the insulation material 400 and the exterior material 500. .

Accordingly, the first and second binding bands 610 and 620 are inserted into the first and second binding holes 340 and 350 and are coupled to surround the outer peripheral surface of the exterior material 500 and can be fixed by the fastening member.

The rib guide groove 360 is formed in the central reinforcement plate 320 on the upper part of the second fastening hole 350.

The rib guide groove 360 is formed to be open from the central reinforcement plate 320 toward the unit panel portion 200, and the reinforcing rib 230 of the unit panel portion 200 is coupled to the rib guide groove 360. .

The insulation material 400 is coupled to the space between the lower ribs 211 and 221 and the upper ribs 212 and 222 of the first and second unit panels 210 and 220.

The insulation material 400 is made of polyethylene. Although the thickness of the insulation material 400 is greater than 25 mm, which is the width of the reinforcing rib 230, the insulation material 400 is fixed by covering the outer peripheral surface of the insulation material 400 with the exterior material 500. If this is done, the insulation material 400 may be partially compressed by the force with which the exterior material 500 is fixed.

The exterior material 500 is installed in a structure that covers the outside of the insulation material 400 and is an aluminum plate in which vertical waveforms are continuously formed.

The exterior material 500 is coupled to surround the outer peripheral surface of the insulation material 400 coupled to the space portion of the unit panel portion 200.

In addition, the binding band portion 600 is coupled to the first and second binding holes 340 and 350 formed in the earthquake-resistant stopper 300 and is wound around the outer peripheral surface of the exterior material 500 to provide resistance to lateral pressure generated due to an earthquake. will have

The binding band portion 600 includes a first binding band 610 and a second binding band 620.

The first binding band 610 is made of stainless steel, has a thin strip shape, and is formed to a height of 50 mm.

The first binding band 610 is formed to be longer than the length of the exterior material 500, and a fastening member is provided at one end.

The second bonding band 620 is made of the same stainless steel material as the first bonding band 610, is made in the shape of a thin strip, and is formed to a height of 25 mm.

Here, the first connection band 610 is formed higher than the height of the second connection band 620.

In general, the structure of a water tank is inevitably weak because the height of the lower 1M receives the most lateral pressure. As described above, the first binding band 610, which is formed to be higher than the second binding band 620, is a water tank. It effectively supports the lateral pressure at the bottom and prevents the water tank from expanding.

The following describes the construction method of the lower fixing device of a stainless steel cylindrical water tank with an earthquake-resistant function according to the present invention.

First, as shown in FIGS. 5 to 7, a stainless steel plate is cut with a laser on the upper surface of the concrete foundation (C), seated to match the floor standard of the cylindrical water tank, and then joined by welding to form the flooring material (100). (ST10)

After the lower rib 211 of the first unit panel 210 is erected vertically to be the same as the outer shape of the flooring 100, the ground portion where the flooring 100 and the lower rib 211 meet is fixed by welding, and the first unit panel 210 is fixed by welding. The step of setting up the unit panels 210 in succession and fixing them by welding is repeated to form the outer shape of the lower part of the water tank.

In addition, when the lower rib 222 of the second unit panel 220 is seated so as to overlap the upper rib 212 of the first unit panel 210, the ground portion of the upper rib 212 and the lower rib 222 is formed. The welding fixation step is repeated to form the outer shape of the upper part of the water tank (ST20).

When the unit panel unit 200 is installed on the upper part of the flooring material 100 as described above, the seismic stopper 300 is fixed at four locations divided at 90° on the outside of the unit panel unit 200 to prevent lateral pressure generated by an earthquake. You will be able to respond to .

The earthquake-resistant stopper 300 is in close contact with the concrete foundation (C) and the outer peripheral surface of the unit panel portion 200 and is fixed through anchor bolts 330.

First, anchor bolts 330 are embedded and installed on the upper surface of the concrete foundation (C) where the seismic stopper 300 is to be installed so that the upper end protrudes above the ground at a certain height.

The anchor hole 311 formed in the lower support plate 310 is coupled to the anchor bolt 330, the lower support plate 310 is seated on the concrete foundation (C), and the vertical support plate 370 is connected to the outer peripheral surface of the unit panel portion 200. After attaching the rib guide groove 360 formed on the central reinforcing plate 320 to the reinforcing rib 230 of the unit panel portion 200, fastening the nut to the anchor bolt 330 to secure the seismic stopper 300. Fix it. (ST30)

By fixing the seismic stopper 300 to the unit panel portion 200 and the concrete foundation C as described above, a binding force is formed when vibration due to an earthquake occurs, thereby preventing excessive separation and overturning.

When the earthquake-resistant stopper 300 is fixed to the concrete foundation (C) and the unit panel portion 200, the lower rib 211 and upper rib 212 of the first unit panel 210 and the second unit panel 220 A thermal insulation material 400 is installed in the space between the lower rib 221 and the upper rib 222.

The insulation material 400 is cut to a length equal to the outer shape of the cylindrical water tank.

When installing the insulating material 400 as described above, the portion where the central reinforcing plate 320 of the earthquake-resistant stopper 300 is located is partially cut with a cutting member such as a knife so that the central reinforcing plate 320 is located on the outer side of the insulating material 400. (ST40)

With the insulating material 400 installed, the exterior material 500 is coupled to the outer circumferential surface of the insulating material 400 to give the cylindrical water tank an attractive appearance.

The exterior material 500 is configured to form a continuous waveform in the vertical direction, is cut to the same length as the insulation material 400, is joined, and is secured with a fixing screw or rivet at a certain position to prevent the exterior material 500 from unfolding again. Fix it. (ST50)

When the exterior material 500 is installed on the entire outer peripheral surface of the insulation material 400 as described above, the exterior material 500 is inserted through the first binding hole 340 formed at the bottom of the earthquake-resistant stopper 300. Wrap around the outer circumference of the and secure it.

In addition, the second fastening band 620 is inserted through the second fastening hole 350 formed at the top of the earthquake-resistant stopper 300 and wrapped around the outer peripheral surface of the exterior material 500 to secure it.

Here, fastening members are formed at the ends of the first and second connection bands 610 and 620 and are firmly fixed, so that the first and second connection bands 610 and 620 do not come loose. (ST60)

In general, the highest lateral pressure is formed at the bottom of a cylindrical water tank less than 1M in height, and higher lateral pressure is formed toward the bottom of the water tank.

The first binding band 610 is formed to be 50 mm taller than the height of the second binding band 620, which is 25 mm, in order to effectively resist the lateral pressure formed at the bottom of the water tank, thereby not only preventing the water tank from expanding, but also preventing the water tank from expanding. By preventing damage to the weld zone, damage to the insulation material 400 and the exterior material 500 can be prevented.

Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

100: Flooring
200: unit panel unit 210: first unit panel
220: Second unit panel 230: Reinforcement rib
300: Earthquake-resistant stopper 310: Lower support plate
320: Central reinforcement plate 330: Anchor bolt
340: first connection hole 350: second connection hole
360: Rib guide groove 370: Vertical support plate
380: Upper support plate
400: Insulating material
500: Exterior material
600: Binding band part 610: First binding band
620: Second binding band

Claims (9)

A flooring material (100) formed on the upper surface of the concrete foundation (C) to form the bottom surface of a cylindrical water tank;
The first unit panel 210 is continuously fixed vertically along the edge of the flooring 100, and the second unit panel 220 is continuously fixed on the top of the first unit panel 210 to create the external shape of the cylindrical water tank. A unit panel portion (200) forming a;
It is located at four locations divided at 90° on the outside of the unit panel portion 200, and accommodates the lower rib 211 of the first unit panel 210 and the upper rib 212 of the first unit panel 210 and the first unit panel 210. 2. An earthquake-resistant stopper (300) that accommodates the reinforcing rib (230) formed by fixing the lower rib (221) of the unit panel (220) and forms a binding force when vibration occurs due to an earthquake.
Insulating material 400 inserted between the lower ribs 211 and 221 and the upper ribs 212 and 222 of the first and second unit panels 210 and 220;
An exterior material 500 formed to cover the outside of the insulation material 400 and extend from the top to the bottom of the unit panel portion 200;
A binding band portion 600 that is coupled to the first and second binding holes 340 and 350 formed in the earthquake-resistant stopper 300 and is wrapped around the outer peripheral surface of the exterior material 500 to provide resistance to lateral pressure generated by an earthquake. A lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function, comprising:
In claim 1,
The unit panel portion 200 is,
A first unit panel 210 fixed to the upper edge of the flooring 100 and welded to the flooring 100;
a second unit panel 220 fixed to the top of the first unit panel 210;
It includes a reinforcing rib 230 formed at a contact portion of the upper part of the first unit panel 210 and the lower part of the second unit panel 220,
The first and second unit panels 210 and 220 are,
Lower ribs 211 and 221 formed at the lower end;
Upper ribs 212 and 222 formed at the upper end;
Vertical plates 213 and 223 vertically connected to ends of the lower ribs 211 and 221 and the upper ribs 212 and 222;
Two rows of reinforcement grooves 214 and 224 are formed at regular height intervals on the vertical plates 213 and 223,
The reinforcing rib 230 has an earthquake-resistant function, characterized in that it is formed by fixing the ground portion of the upper rib 212 of the first unit panel 210 and the lower rib 221 of the second unit panel 220 by welding. A lower fixing device for a stainless steel cylindrical water tank.
In claim 1,
The earthquake-resistant stopper 300,
A lower support plate (310) fixed to the concrete foundation (C) and having a plurality of anchor holes (311) formed thereon;
A central reinforcement plate 320 formed vertically at the upper center of the lower support plate 310;
Anchor bolts 330 that are embedded in the concrete foundation (C) and secure the lower support plate 310 to the concrete foundation (C);
A first connection hole 340 formed in the lower part of the central reinforcement plate 320 adjacent to the lower support plate 310 and into which the first connection band 610 is inserted;
a second connection hole 350 formed on the upper part of the central reinforcement plate 320 into which the second connection band 620 is inserted;
A stainless steel cylindrical water tank with an earthquake-resistant function, characterized in that it includes a rib guide groove 360 formed in the central reinforcement plate 320 on the upper part of the second fastening hole 350 to be open toward the unit panel portion 200. Lower fixture.
In claim 3,
A lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function, further comprising a vertical support plate 370 formed vertically at an end of the central reinforcement plate 320 and in close contact with the outer peripheral surface of the unit panel portion 200. .
In claim 3,
It further includes an upper support plate 380 formed perpendicular to the end of the central reinforcement plate 320 above the rib guide groove 360 and in close contact with the outer peripheral surface of the second unit panel 220 of the unit panel portion 200. A lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function.
In claim 3,
The first and second connection holes 340 and 350 are,
A lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function, characterized in that the unit panel portion 200 and the adjacent central reinforcing plate 320 are spaced apart from each other by a thickness including the insulation material 400 and the exterior material 500. .
In claim 1,
The binding band portion 600 is,
A first connection band 610 inserted into the first connection hole 340 of the earthquake-resistant stopper 300 and wound around the outer peripheral surface of the exterior material 500;
It includes a second fastening band 620 that is inserted into the second fastening hole 350 of the earthquake-resistant stopper 300 and wrapped around the outer peripheral surface of the exterior material 500,
The first and second binding bands 610 and 620 are cut longer than the circumference of the exterior material 500, and fastening members are fixed to the ends of the first and second binding bands 610 and 620 to secure the exterior material 500. A lower fixing device for a stainless steel cylindrical water tank with an earthquake-resistant function, characterized in that the first and second fastening bands 610 and 620 are wound around the outer peripheral surface, respectively, and the fastening member is pulled and fixed.
In claim 7,
The height of the first connection band 610 is formed to be higher than the height of the second connection band 620, so as to support the lateral pressure transmitted to the bottom of the cylindrical water tank and prevent damage to the weld zone of the cylindrical water tank. A lower fixing device for a stainless steel cylindrical water tank.
Cutting a stainless steel plate on the upper surface of the concrete foundation (C) with a laser, seating it to match the bottom standard of a cylindrical water tank, and then joining it by welding to form the flooring material (100);
After erecting the lower rib 211 of the first unit panel 210 vertically so that it has the same external shape as the flooring 100, the step of fixing the ground portion where the flooring 100 and the lower rib 211 meet by welding is repeated. After forming the outer shape of the lower part of the water tank and seating the lower rib 222 of the second unit panel 220 on the upper rib 212 of the first unit panel 210 to overlap, the upper rib 212 and the lower rib Repeating the step of fixing the ground portion of (222) by welding to fix the unit panel portion 200 to form the outer shape of the upper part of the water tank;
The lower support plate 310 is seated on four concrete foundations (C) divided at 90° on the outside of the unit panel portion 200, and the vertical support plate 370 is in close contact with the outer peripheral surface of the unit panel portion 200. Fixing the seismic stopper 300 by fastening a nut to the anchor bolt 330;
Mounting a thermal insulation material (400) in the space formed between the lower ribs (211) (221) and the upper ribs (212) (222) of the first and second unit panels (210) (220);
Wrapping an exterior material 500 having a vertical wave shape around the outer peripheral surface of the insulation material 400 and fixing the insulation material 400 so that it is not exposed to the outside;
The first fastening band 610 is inserted into the first fastening hole 340 formed at the bottom of the earthquake-resistant stopper 300, and the outer peripheral surface of the exterior material 500 is wrapped once and fixed through a fastening member, and the upper end of the earthquake-resistant stopper 300 is fixed. The lower part of a stainless steel cylindrical water tank with an earthquake-resistant function, comprising the step of inserting the second binding band 620 into the second binding hole 350 formed in and fixing it in the same manner as the first binding band 610. Fixture construction method.

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