KR20200107193A - Construction method of noise reduction type parking lot - Google Patents

Abstract

Disclosed is a parking lot construction method, which includes: a base step of forming a base layer; a floor slab forming step of forming a floor slab on the base layer; a drain plate installing step of installing a drain plate connected to a collecting well on the floor slab; a concrete placing step of placing concrete onto the drain plate; a groove forming step of forming a groove having a predetermined depth on an upper surface of the concrete in a predetermined shape; and a repair liquid inserting step of inserting repair liquid heated by applying heat to the groove to solidify the same in a solid state in the groove. Therefore, the parking lot construction method can prevent a noise from being generated by cracks.

Description

Construction method of noise reduction parking lot {CONSTRUCTION METHOD OF NOISE REDUCTION TYPE PARKING LOT}

This technology relates to a parking lot construction method.

A parking lot is a space for parking vehicles.When constructing a parking lot, a drain plate is installed on the base and then concrete is put on the installed drain plate to cure for 3 to 4 days, and the vehicle is built by applying a finishing material on the cured concrete. I am making it possible to put it.

In addition, when a period of time has elapsed, areas in contact with the ground, such as the basement outer wall or the bottom floor, may seep into the groundwater or groundwater due to the water pressure of the groundwater, causing leakage. Rainwater, etc. may flow into the basement without being discharged through the drainage path.

In particular, when a large building or building is newly constructed, the construction of an underground structure is indispensable, and most of these underground structures are constructed and used as an underground parking lot to secure the maximum gross area of the above-ground building. It is required to construct a solid basement floor that is not easily deformed. In addition, when excavation is performed in depth, the internal pressure for groundwater is lowered in the excavated stratum, so that groundwater flows from the surroundings and can penetrate into the basement floor.Therefore, drainage construction to properly drain it and waterproofing treatment on the upper part of concrete are accompanied. Should be.

1 is a cross-sectional view of a conventional parking lot.

In the parking lot construction method, a base layer (1) is formed by flatly forming an oyster finish surface with residual soil, gravel, or burr on the excavated layer, and placing mortar on it.

Then, mortar is placed on the base layer 1 to form the floor slab 2 to a predetermined height, but the floor slab 2 is capable of flowing the groundwater discharged from the floor slab 2 into the water collection well. So that the surface of the floor slab (2) is given no gradient or gradient to pour concrete.

Then, a drain plate 3 is installed on the floor slab 2 and formed in the water collecting well 5 or the floor slab 2 and connected to the water collecting well 5 by a trench. The concrete layer 4 is formed to a predetermined height by pouring mortar. Finally, in order to prevent cracks from occurring in the concrete layer 4 due to contraction and expansion due to temperature change, and to prevent the drain plate 3 from being lifted from the base layer 1, the depth set in the concrete layer 4 The groove is formed in a rectangular shape.

Parking lots are manufactured in the same way as above.

Figure 2 shows the problem of a conventional parking lot.

However, the parking lot constructed in this way has a problem that noise is generated when the vehicle is moving. This noise was caused by cracks generated along the grooves formed in the concrete layer 4. That is, in order to prevent cracks, cracks are generated along the grooves formed in the concrete layer 4, and eventually the concrete layer 4 is divided independently, and the direction in which the divided concrete layers 4 get closer to each other when the vehicle moves. It was moved to and bumped, causing noise.

Another cause is that the drainage plate 3 located under the concrete layer 4 does not come into contact with the floor slab 2 due to this crack and is lifted. In this case, when the vehicle moves the lifted concrete layer 4, it is lifted by the vehicle. The concrete layer 4 moved downward and the drain plate 3 collided with the floor slab 2, causing noise.

In the above case, the parking lot contractor must repair the parking lot to solve the problem of the parking lot, but the cost of repair was higher than the parking lot construction cost, which was incurred as a serious damage to the contractor. There was a problem that it could not be used as long as it was due.

Korean Patent Application Publication No. 10-2018-0042683 "A FLOOR CONSTRUCTION METHOD OF NOISE REDUCTION TYPE UNDERGROUND PARKINGLOT"

An object of the present invention is to solve the above-described problem, and to provide a method for constructing a parking lot in which noise is not generated by cracks.

In addition, an object of the present invention is to provide a parking lot construction method that reduces the noise of the parking lot at low cost.

In addition, an object of the present invention is to provide a parking lot construction method having a very short maintenance period.

The technical problem to be achieved by the present invention is not limited to the technical problems mentioned above, and other technical problems that are not mentioned can be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. will be.

The parking lot construction method includes a base step of forming a base layer, a floor slab forming step of forming a floor slab on the base layer, a drain plate installation step of installing a drain plate connected to the collecting well on the floor slab, and pouring concrete on the drain plate. Including a concrete pouring step, a groove forming step of forming a groove of a set depth on the upper surface of the concrete into a set shape, and a repairing liquid injection step of injecting a repair liquid heated by applying heat to the groove to solidify in the groove. do.

Here, in the step of introducing the repair liquid, a space in which the base plate and the roller unit installed under the base plate, the heat supply unit installed on the base plate, and the repair solid are disposed therein is formed, and the heat of the heat supply unit is applied. A storage unit disposed in an area to convert the repair solid of the internal space into a repair liquid, and a discharge unit having a size set so that the storage unit communicates the inside and the outside, and the end is inserted into the groove, It is characterized in that the maintenance liquid is introduced into the groove in a liquid state by using a heating and moving device including an injection unit through which the maintenance liquid flows and can inject the maintenance liquid into the groove.

Here, the heat supply unit of the heating transfer device includes a support portion formed to increase in diameter from the bottom to the upper portion, and the uppermost portion of the support portion is formed to match the diameter of the lowermost portion of the storage portion, and the storage portion is supported by the support portion. To do.

Here, the support part of the heating and moving device is characterized in that it comprises an auxiliary support part for supporting the circumferential surface of the storage part including an inner surface rounded upward at an angle set at the top.

Here, the input unit is characterized in that it comprises a communication unit installed in communication with the storage unit, a flexible unit connected to the communication unit to move flexibly, and a nozzle unit connected to the flexible unit and having an outlet having a set size.

Here, the heating and moving device is made of a material that is not flexible, and includes a grip part extending to a length set from the input part.

As described above, the present invention prevents the concrete layer from being partitioned by using a repair liquid that is formed in the form of a gel when it cools down, so that noise is not generated even when the vehicle moves.

In addition, according to the present invention, the repair liquid moves through the cracks and fills the space between the repair plate and the base layer to prevent the gap between the repair plate and the base layer, so that noise is not generated even when the vehicle moves.

In addition, the present invention uses a low-cost maintenance liquid to reduce the noise of the parking lot, so the cost of maintenance is very low.

In addition, in the present invention, since the maintenance time is about 10 minutes, the parking lot can be used immediately after maintenance.

1 is a cross-sectional view of a conventional parking lot.
Figure 2 shows the problem of a conventional parking lot.
Figure 3 is a block diagram showing the steps of the present inventors parking lot construction method.
4 shows a situation that occurs when the repair liquid of the present invention is injected into a groove.
5 is a perspective view of the heating device of the present invention.
6 is a side view of the heating device of the present invention.
7 is an enlarged view of D of FIG. 6.
8 is an enlarged view of E in FIG. 6.
9 is an enlarged view of F in FIG. 6.

Hereinafter, an embodiment of the present invention will be described in detail through exemplary drawings. However, this is not intended to limit the scope of the present invention.

In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, the size or shape of the components illustrated in the drawings may be exaggerated for clarity and convenience of description. In addition, terms specifically defined in consideration of the configuration and operation of the present invention are only for describing the embodiments of the present invention, and do not limit the scope of the present invention.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated. In addition, terms such as "... unit", "... group", "module", and "device" described in the specification mean a unit that processes at least one function or operation, which is implemented by a combination of hardware and/or software. Can be.

Figure 3 is a block diagram showing the steps of the present inventors parking lot construction method.

The inventors' parking lot construction method includes a base step (S1), a floor slab formation step (S2), a drain plate installation step (S3), a concrete placement step (S4), a groove formation step (S5), and a repair solution input step (S5). .

The base step (S1) is a step of forming a base layer. The base layer is the lowermost layer of the parking lot, which is the base layer, and is formed by flattening the finished surface using leftover soil, gravel, burr, etc. on the excavated layer, and placing mortar on it.

The floor slab formation step (S2) is a step of forming a floor slab on the base layer, and the floor slab is formed by pouring concrete with a gradient and no gradient so that groundwater can flow into a collecting well installed adjacent to the base layer. .

Drainage plate installation step (S3) refers to a step of installing a drainage plate on the formed floor slab and connecting the water collection well or the water collection well formed on the floor slab with a trench. The drain plate is formed by connecting a plurality of pockets with a diameter narrowing from an upper side to a lower side.

The concrete placing step (S4) is a step of forming concrete by a set height by placing mortar on a drain plate.

The groove forming step (S5) is a step of preventing cracks caused by contraction and expansion of the concrete by forming a groove of a set depth in the concrete formed by the concrete placing step (S4) in a set shape. The depth of the groove should not be at least not deeper than the height of the concrete layer. The groove may be formed in a rectangular shape when the concrete layer is observed from above. However, the shape of the groove is not limited to a rectangular shape, and may be variously modified depending on the operator.

4 shows a situation that occurs when the repair liquid of the present invention is injected into a groove.

The maintenance liquid injection step (S5) is a step of injecting the heated maintenance liquid into the groove and injecting it into the groove. The repair liquid cools and hardens into a solid. The repair liquid may be a heated crack repair adhesive. Therefore, when the repair liquid cools, it becomes a gel-like solid. Therefore, the grooves of the concrete can be filled and bonded to each other by the solid cooled by the repair liquid. Also, since the repair liquid is liquid, it can be filled in cracks formed along the grooves. Then, when the repair liquid cools and becomes a gel-like solid, it is placed in the crack to fill the crack.

Accordingly, when the vehicle is moving, the concrete partitioned by the groove and the crack does not collide, and noise is not generated.

In addition, when the repair liquid is injected into the groove, it can move along the crack and move to the bottom of the drain plate. The repair liquid that has moved to the bottom of the drain plate hardens between the floor slab and the drain plate and becomes a gel-like solid, which bonds the drain plate to the bottom slab. Accordingly, the drain plate located under the concrete floor does not hit the floor slab and no sound is generated.

As described above, in the present invention, the repair liquid is not hardened by heating and must be kept in a liquid state and cooled after being introduced into the groove to become a gel-like solid. In the present invention, a heating and moving device 100 was devised for this purpose.

5 is a perspective view of the heating device of the present invention.

6 is a side view of the heating device of the present invention.

7 is an enlarged view of D of FIG. 6.

8 is an enlarged view of E in FIG. 6.

9 is an enlarged view of F in FIG. 6.

The heating and moving device 100 includes a base plate 110, a roller unit 120, a heat supply unit 130, a storage unit 140, an input unit 150, and an extension grip unit 160. In addition, it includes a support pillar 170, a circumferential frame 180, a support plate 181, a fire prevention device 190, and the like.

The base plate 110 has a flat shape and provides an area on the upper surface in which each component is to be installed. On one side of the base plate 110, a handle 200 that an operator can push to move the heating and moving device 100 is formed.

A roller part 120 is formed under the base plate 110. The roller unit 120 is configured to assist the movement of the base plate 110 and supports the base plate 110 from the bottom, but rotates when a force is applied to assist the heating and moving device 100 to move. The roller unit 120 is formed symmetrically under the base plate 110 to be symmetrical since it must support the base plate 110 horizontally. Here, symmetry means the vertices of a triangle and a vertex of a square.

Support columns 170 are installed to be spaced apart from each other on the upper surface of the base plate 110. The support pillar 170 is formed in a straight shape toward the top. It is preferable that the number of support pillars 170 form a rectangular space therein.

A circumferential frame 180 is formed on the outer surface of the support pillar 170. The circumferential frame 180 is composed of four to close the inside and the outside of the space formed by the support pillar 170 to form a space having a shape set therein. Four circumferential frames 180 may be installed along the circumference of the support pillars 170 on the lower side, and four circumferential frames 180 may be installed along the circumference of the support pillars 170 separated from each other.

Any one of the four circumferential frames 180 is not shown, but may be connected to the support pillar 170 by hinge coupling on one surface. Accordingly, the circumferential frame 180 hinged with the support pillar 170 may be rotated with respect to the support pillar 170.

A heat supply unit 130 may be installed in an inner space partitioned by the support pillar 170 and the circumferential frame 180 of the upper surface of the base plate 110. The heat supply unit 130 is configured to apply heat toward the top. Meanwhile, a support bracket 182 may be installed between the base plate 110 and the heat supply unit 130. The support bracket 182 is formed in a shape in which the lower surface is in contact with the upper surface of the base plate 110, and the end side is rounded toward the upper portion. The lower circumference of the heat supply unit 130 is formed to be round, and the circumference of the heat supply unit 130 may be supported by the circumference of the support bracket 182. Through this, the heat supply unit 130 does not flow much even if an external shock is generated.

In addition, the heat supply unit 130 is supported by the support plate 181 formed on the circumferential frame 180 and does not flow due to external impact. The support plate 181 is formed to extend from the inner surface of the circumferential frame 180 toward the inner direction. The end of the support plate 181 is formed to be round. Therefore, the support plate 181 supports the heat supply unit 130 located therein around. That is, since the heat supply unit 130 is supported by the support bracket 182 at the bottom, and is supported by the support plate 181 around the periphery, it does not move even if an external impact is applied.

On the other hand, the heat supply unit 130 is composed of a support unit 132 and a heat source supply tube. The support part 132 is located above the heat source supply container. The portion supported by the above-described support plate 181 and support bracket 182 is a heat source supply container. The support part 132 is located at the top of the heat source supply container to apply heat to the upper side, discharges fuel stored by the heat source supply container to the outside, and continuously applies heat, but can support the storage part 140 from the top. .

The support part 132 is formed to increase in diameter from the bottom to the top. That is, the diameter increases continuously from the lowermost part to the uppermost part of the support part 132. The diameter of the uppermost portion of the support portion 132 is formed to match the diameter of the lowermost portion of the storage portion 140. Therefore, when the storage unit 140 is disposed on the support unit 132, it can be stably supported.

An auxiliary support part 133 is formed around the support part 132. The auxiliary support part 133 plays a similar role to the support bracket 182. The auxiliary support part 133 is formed to include an inner surface rounded upward at an angle set on the upper part of the support part 132. At least three auxiliary support portions 133 are formed along the circumference of the support portion 132.

The storage unit 140 has a space formed therein, the upper part is open, and is formed to have a rounded circumferential surface. The lower part of the storage part 140 is supported by the upper part of the support part 132. In addition, the lower circumference of the storage unit 140 is supported by an auxiliary support unit 133 formed to be rounded. That is, three points may be supported by the auxiliary support part 133.

Meanwhile, the storage unit 140 may also be supported by the support plate 181. The circumferential frame 180 installed along the upper support pillar 170 described above may be installed along the circumference of the storage unit 140. On the inner surface of the circumferential frame 180, a support plate 181 is also formed in a protruding shape toward the inside. This support plate 181 supports the circumference of the storage unit 140.

That is, the storage unit 140 is also supported on the lower side by the support unit 132 and at the same time supports the lower circumference through the auxiliary support unit 133, but the outer circumference is supported by the support plate 181 so that it does not flow due to external impact. Does not.

The storage unit 140 may be located inside the crack repair adhesive through the open portion. The crack repair adhesive exists as a solid before heat is applied, then transforms into a liquid repair liquid when heat is applied, and then exists in the form of a gel when heat is blocked and hardened. The crack repair adhesive located in the storage unit 140 is continuously supplied with heat by the heat supply unit 130 located at the lower side, so this crack repair adhesive is applied to the storage unit 140 in the state of a repair liquid by continuously applied heat. Can be kept.

The input unit 150 is connected to the storage unit 140. The input unit 150 is formed to communicate the inside and the outside of the storage unit 140, and a discharge unit having a size enough to be inserted into the above-described groove is formed at one end. The repair liquid flows while the discharge part of the input unit 150 is inserted into the groove, so that the repair liquid can be injected into the groove. The repair liquid injected into the groove is transformed into a gel-like solid as described above.

The input unit 150 includes a communication unit, a flexible unit, and a nozzle unit.

The communication unit refers to a portion that communicates with the storage unit 140, and although not shown, the flow path may be blocked or opened by a valve. One side of the communication unit is connected to the storage unit 140 and the other side is connected to one side of the flexible unit. The flexible portion is formed to be flexible and can be moved flexibly. The nozzle portion is formed to be firmly the same as the communication portion, and is connected to the other side of the flexible portion. The other side of the nozzle part is the above-described discharge part, which is formed in the form of a very narrow and thin nozzle and can be fitted into the groove.

A grip unit 160 may be formed in the input unit 150. More precisely, the outer surface of the nozzle unit may be connected to the grip unit 160 and the outer surface. The grip unit 160 is formed in a set length and formed in the form of a rod. The grip unit 160 is a part that can be gripped by an operator, and the input unit 150 can be more easily adjusted. One surface of the circumference of the other side of the grip unit 160 may contact the outer surface of the nozzle unit.

The operator can inject the repair liquid into the groove in the following way. It is preferable to act as a group of two. Worker A grips and pushes the handle 200, and worker B grips the end of the grip part 160 and moves the nozzle part in the groove in accordance with the speed of the worker A along the longitudinal direction of the groove.

If the repair work is performed in this way, the repair liquid can be injected into the groove very quickly. This repair liquid dries quickly and becomes a solid in the form of a gel, which can bond between the concrete groove or the drain plate and the floor slab, which takes about 10 minutes. And, the cost of repair is very little consumed.

Although the present invention has been illustrated and described with reference to specific embodiments, it is understood in the art that the present invention can be variously improved and changed within the scope of the technical spirit of the present invention provided by the following claims. It will be obvious to a person of ordinary knowledge.

S1: Base step S2: Floor slab formation step
S3: Drain plate installation step S4: Concrete pouring step
S5: Groove formation step S5: Repair amount input step
100: heating moving device 110: base plate
120: roller unit 130: heat supply unit
132: support 133: auxiliary support
140: storage unit 150: input unit
160: grip part 170: support column
180: circumferential frame 181: support plate
182: support bracket 190: fire prevention device
200: handle

Claims (6)

A base step of forming a base layer;
A floor slab forming step of forming a floor slab on the base layer;
A drain plate installation step of installing a drain plate connected to the water collecting well on the floor slab;
A concrete placing step of placing concrete on the drain plate;
A groove forming step of forming a groove having a set depth on the upper surface of the concrete into a set shape; And
Injecting the heated repair liquid by applying heat to the groove so that it solidifies into a solid in the groove
Parking lot construction method comprising a. The method of claim 1,
In the remuneration amount input step,
A base plate, a roller part installed under the base plate, a heat supply part installed above the base plate, and a space in which a repair solid is disposed are formed, and the inner space is disposed in an area to which heat of the heat supply part is applied. A storage unit in which the repairing solid of the unit is converted into a repairing liquid, and a discharge unit having a size set so that the storage unit communicates with the inside and outside, and the end of which is set to be inserted into the groove is formed. Injecting the repair liquid into the groove in a liquid state by using a heating and moving device composed of an injection unit capable of injecting the repair liquid into the groove
Parking lot construction method, characterized in that. The method of claim 2,
The heat supply unit of the heating device
It includes a support portion formed to increase in diameter from the bottom to the top,
The uppermost portion of the support portion is formed to match the diameter of the lowermost portion of the storage portion, and the storage portion is supported by the support portion.
Parking lot construction method characterized by The method of claim 3,
The supporting part of the heating moving device
Comprising an auxiliary support portion for supporting the circumferential surface of the storage unit including an inner surface rounded upward at an angle set at the top
Parking lot construction method, characterized in that. The method of claim 2,
The input part
A communication unit installed in communication with the storage unit, a flexible unit connected to the communication unit to move flexibly, and a nozzle unit connected to the flexible unit and having an outlet having a set size
Parking lot construction method characterized by The method of claim 5,
The heating and moving device,
Made of a non-flexible material and including a grip part extending to a length set from the input part
Parking lot construction method, characterized in that.

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