KR102822205B1 - Sidewalk type penetration storage facility and sidewalk type penetration storage tank and its construction method - Google Patents

Abstract

The present invention relates to a sidewalk-type infiltration retention facility and a sidewalk-type infiltration retention tank and a construction method thereof, which prevents rainwater from rushing into a rainwater catchment all at once, that is, disperses rainwater to reduce flood damage, and expands the rainwater retention space by draining rainwater into a separate permeable layer, thereby dispersing rainwater even in heavy rain with strong intensity.
The sidewalk-type infiltration retention facility according to the present invention comprises: a sidewalk-type infiltration retention tank (100) installed underground in a sidewalk to introduce rainwater from the sidewalk and road and then drain it; a permeable layer (200) constructed underground along the sidewalk-type infiltration retention tank to permeate rainwater drained from the sidewalk-type infiltration retention tank into the ground; and a perforated pipe (210) buried in the permeable layer to induce and drain rainwater inside the permeable layer. In addition, it comprises an emergency drain pipe (220) that is arranged so as to slope downward toward the rainwater receiver between the perforated pipe and a rainwater receiver installed on the roadside, and is connected to the perforated pipe and the rainwater receiver on both sides to drain rainwater in the perforated pipe to the rainwater receiver. The sidewalk-type infiltration retention tank comprises: a retention tank body (10) having a storage space formed inside, a sidewalk-side inflow portion formed at the top, and a rainwater drain portion formed at the bottom in a direction opposite to the sidewalk-side inflow portion; A cover (20) installed at the side inlet of the main body of the storage tank; and a filter (30) installed inside the main body of the storage tank to filter rainwater and then drain it into the ground, the cover comprising a combination of a working port (21), a nonporous cover part (22) that prevents rainwater from passing through when the working port is opened and closed, and a permeable part (23) that introduces rainwater into the inside of the main body of the storage tank through an internal passage.

Description

{Sidewalk type penetration storage facility and sidewalk type penetration storage tank and its construction method}

The present invention relates to a sidewalk-type infiltration storage tank, and more specifically, to a sidewalk-type infiltration storage facility that temporarily stores rainwater on the sidewalk and road sides by creating a storage space under the sidewalk and allows it to infiltrate into the ground, and when the stored rainwater becomes overloaded, drains it in conjunction with an existing rainwater drainage facility, and a sidewalk-type infiltration storage tank and a construction method thereof.

Due to urbanization, the natural permeable surface area decreases as the building and road areas increase, which reduces the rainwater storage and infiltration capacity of the ground, reducing the time for rainwater to reach urban rivers when rainfall occurs, increasing peak flow, and causing river overflows and flooding within cities.

In addition, an increase in impermeable surface area reduces the amount of rainwater that infiltrates underground, lowering the groundwater level and causing urban rivers to dry up and cause seepage.

Due to changes in rainfall characteristics caused by climate change, rainfall intensities higher than the design frequency of conventional large-crete rainwater gutters and rainwater pipes are occurring more frequently, causing problems with low-lying areas being flooded.

In addition, damage, cracks, and missing joints in existing, aged rainwater pipes, as well as soil, fallen leaves, and trash deposits inside the pipes, are reducing drainage capacity, causing flooding in nearby areas.

In addition, pollutants such as fine dust in the air, soil, heavy metals, organic matter, and oil generated by automobile driving and human activities accumulate on the surface, and rainwater containing a large amount of pollutants is directly discharged into rivers in a short period of time, causing adverse effects on water quality and aquatic ecosystems.

In addition, due to recent abnormal climate and urban warming, flooding and river overflow damage caused by localized heavy rain in urban areas are rapidly increasing, and pollution of the surrounding environment is worsening due to pollutants discharged from roadsides.

Patent documents that can confirm this background technology include registered patent no. 10-2082978 and registered patent no. 10-2241363.

The problems of prior art can be summarized as follows.

1. Increased flood damage due to increased peak runoff

As impermeable surfaces increase, the infiltration and storage of rainwater decrease and the runoff increases. In particular, as the frequency of heavy rain increases, peak flow increases further, shortening the time for rainwater to be collected in low-lying areas, and more rainwater stays on the roadside, increasing flood damage.

2. Flood damage increases due to rainwater drainage bottlenecks

Due to impermeable surfaces and heavy rain, a large amount of rainwater is quickly collected and rushes into a limited number of rainwater gutters, creating a bottleneck shape where rainwater accumulates. This causes rainwater to remain in low-lying areas for a longer period of time, increasing flood damage.

3. Loss of drainage function due to clogging of the rainwater drain cover or rubber plate covering

As various types of waste, such as fallen leaves and cigarette butts, accumulate at the entrance of the rainwater gutters, roads can become flooded even with a small amount of rain. In addition, when a rubber sheet is placed over the cover to prevent foul odors from seeping up from the rainwater gutters, the problem of rainwater not flowing in occurs.

An experiment conducted by the National Disaster and Safety Research Institute found that when a rainwater drain is blocked by trash or covered with rubber sheets, the flooded area increases three times and the flood depth increases by more than 2.3 times.

4. Garbage such as fallen leaves and cigarette butts block drainage pipes, causing rainwater to backflow.

When trash such as cigarette butts and plastic bags flow into the drainage system through the rainwater gutters, the rainwater pipes become clogged, preventing the rainwater from draining properly and causing problems such as backflow into manholes on the road.

Registered Patent No. 10-2082978 Registered Patent No. 10-2241363

The present invention is intended to solve the above-mentioned problems, and provides a sidewalk-type infiltration retention facility and a sidewalk-type infiltration retention tank and a construction method thereof, which prevent rainwater from rushing into a rainwater catchment all at once, that is, disperses the rainwater to reduce flood damage, and expands the rainwater retention space by draining the rainwater to a separate permeable layer, thereby dispersing rainwater even in heavy rain.

In addition, the purpose is to quickly restore the function of the retention tank when an excessive amount of rainwater seeps into the permeable layer through connection with the existing drainage facility.

In addition, the biopolymer concrete inside the retention tank prevents various pollutants such as fallen leaves and cigarette butts mixed in the water flowing in from the road from flowing into the rainwater catchment and causing blockages, thereby maintaining the function of the rainwater pipe, and the pollutants deposited inside are regularly removed to reduce the concentration of fine dust re-suspended on the roadside.

In addition, rainwater or road washing water is filtered by a storage tank and percolated underground to improve the urban water circulation, prevent the death of street trees, and reduce heat islands and tropical nights by cooling the heat of the ground surface.

The sidewalk-type infiltration retention facility according to the present invention is characterized by including a sidewalk-type infiltration retention tank installed underground in a sidewalk to introduce rainwater from the sidewalk and road and then drain it; a permeable layer constructed underground along the sidewalk-type infiltration retention tank to permeate rainwater drained from the sidewalk-type infiltration retention tank into the ground; and a perforated pipe buried within the permeable layer to induce and drain rainwater inside the permeable layer.

The present invention is characterized by including an emergency drain pipe that is arranged so as to slope downward toward the rainwater drain between the perforated pipe and the rainwater drain installed on the roadside, and is connected to the perforated pipe and the rainwater drain on both sides to drain rainwater from the perforated pipe to the rainwater drain.

The above-mentioned infiltration storage tank includes a cover, and the cover is composed of a combination of a working port, a nonporous cover part that prevents rainwater from passing through when the working port is opened and closed, and a permeable part that allows rainwater to flow into the inside of the main body of the storage tank through an internal passage.

The filter installed in the permeable portion of the above cover and the rainwater drainage portion of the above-mentioned infiltration storage tank is characterized by being made of biopolymer concrete.

According to the sidewalk-type infiltration retention facility and sidewalk-type infiltration retention tank and the construction method thereof according to the present invention, rainwater flows into the sidewalk-type infiltration retention tank and is dispersed, thereby reducing the amount and retention time of rainwater collected on the road, thereby reducing flood damage, and furthermore, by increasing the retention capacity through the permeable layer and inducing drainage through the perforated pipe, overflow of the retention facility can be prevented.

In addition, even if an excessive amount of rainwater flows in through the emergency drain pipe, the function of the retention facility is quickly restored by quickly draining the rainwater.

Additionally, the stored rainwater is filtered through a filter and seeps into the ground, improving the urban water cycle, and the evaporation of groundwater lowers the temperature of the sidewalk and prevents the death of street trees.

In addition, non-point source pollutants such as garbage and fine dust particles accumulated in roadside ditches are collected by pushing them into a retention tank using a high-pressure water cleaning vehicle, and the water used to clean the road is filtered through a filter and released underground, creating a clean road environment.

In addition, it has the effect of preventing clogging of pipes by allowing fallen leaves and cigarette butts piled up on the roadside to flow into rainwater drains through rainwater gutters.

In addition, the cover structure of the press-type infiltration tank makes maintenance very easy.

Additionally, the biopolymer concrete's permeability and filter allow for continuous use without permanent blockage.

Figure 1 is a perspective view of the construction status of a sidewalk-type infiltration storage facility according to the present invention.
Figure 2 is a cross-sectional view of a sidewalk-type infiltration storage tank according to the present invention.
Figures 3 and 4 are a road-side perspective view and a sidewalk-side perspective view, respectively, of a sidewalk-type infiltration storage tank according to the present invention.
Figure 5 is a manufacturing process diagram of a cover applied to a press-type infiltration storage tank according to the present invention.
Figure 6 is a plan view showing a permeable layer, a perforated pipe, and an emergency drain pipe applied to a sidewalk-type infiltration storage facility according to the present invention.
Figures 7 to 10 are construction process diagrams of a sidewalk-type infiltration storage facility according to the present invention.

In the following description of the present invention, if it is judged that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the terms described below are terms defined in consideration of the functions in the present invention, and these may vary depending on the intention or custom of the user or operator. Therefore, the definitions should be made based on the contents throughout this specification.

As shown in FIGS. 1 and 2, the sidewalk-type infiltration storage facility according to the present invention includes a sidewalk-type infiltration storage tank (100), a permeable layer (200), and a perforated pipe (210).

A sidewalk-type infiltration storage tank (100) includes a storage tank body (10) that allows sidewalk-side rainwater and road-side rainwater to flow into the ground, a cover (20) that opens and closes the working port of the storage tank body (10) and allows sidewalk-side rainwater to flow in, and a filter (30) that filters foreign substances from rainwater flowing into the inside of the storage tank body (10).

As shown in FIGS. 1 to 4, the main body (10) of the storage tank is provided with a storage space (11) inside for storing rainwater. For this purpose, for example, the main body is formed of a square bottom portion when viewed from a plan view, and wall portions erected on each of the four sides of the bottom portion, and a fixing groove portion is included on the inside of the upper end of the wall portion for fixing the edge of the cover (20).

The upper opening of the main body of the storage tank (10) is a sidewalk inflow port through which rainwater from the sidewalk flows in, and rainwater from the sidewalk flows in through a cover (20) installed in the sidewalk inflow port.

Among the four wall sections, a road-side inflow section (12) is formed in the wall section on the road side, and a rainwater drainage section (13) is formed in the wall section on the opposite side. The road-side inflow section (12) is a hole that allows the road to communicate with the storage space (11) of the main body (10) of the retention tank at a height close to the upper part of the wall section, and on the other hand, the rainwater drainage section (13) is a hole that penetrates the wall section laterally at a height close to the floor section, and due to the difference in their positions, rainwater falling from the sidewalk-side inflow section and the road-side inflow section (12) is drained through the rainwater drainage section (13) on the floor side, and a certain amount of rainwater is stored in the retention space (11).

The road side inlet (12) can be a hole, and a filter made of biopolymer concrete such as the permeable portion (23) and filter (30) described later can also be inserted and installed.

There are at least one road-side inflow port (12) and one rainwater drainage port (13), and the water passage area of the rainwater drainage port (13) is formed to be larger than that of the road-side inflow port (12) to ensure smooth storage and drainage.

The main body of the storage tank (10) can be made of various materials such as concrete and high-strength synthetic resin.

The cover (20) includes a work opening (21), a cover part (22) for opening and closing the work opening (21), and a permeable part (23) through which rainwater passes.

Fig. 5 illustrates a preferred manufacturing process, and the cover (20) is made of materials such as a grid-shaped steel grating (24), a plate-shaped cover part (22), and permeable concrete (preferably, biopolymer concrete).

The steel grating (24) is a base structure that forms both the work opening (21) and the permeable portion (23). For example, half of it is used as the work opening (21) and the other half is used as the permeable portion (33). First, the steel grating (24) is cut and removed in half (leaving a part that is large enough for a worker to enter and a part where the edge of the cover portion (22) is secured, and the inside is removed) to form the work opening (21). A plate-shaped cover portion (22) is prepared in a size slightly larger than the size of the work opening (21), and one side of the cover portion (22) is hingedly connected to the steel grating (24) to install it.

A permeable portion (23) is manufactured by pouring and curing biopolymer concrete (25) on steel grating (24) on which a cover portion (22) is not installed.

For example, biopolymer concrete is made only of aggregates and a polymer binder (biopolymer binder), and the aggregates are coated with the polymer binder and the aggregates are bonded by point contact to form spaces between the aggregates and rainwater flows through these spaces. The polymer binder has very strong adhesiveness and durability, so unlike conventional cement concrete, it does not require sand or filler, and only aggregates are used, so the space between the aggregates is very wide, dramatically improving water permeability, and in particular, since the spaces between the aggregates are all connected, the pores do not become blocked by soil particles, etc., and their performance lasts for many years. For example, a permeable portion (23) made by bonding (immersing, spray coating, etc.) aggregates having a particle size of 8 mm to 10 mm with a biopolymer (e.g., 2 to 10 parts by weight per 100 parts by weight of aggregates) is a porous permeable concrete body having a void ratio of 30% or more (30 to 45%) inside, and in particular, since the adhesive strength of the biopolymer is excellent, sand or filler that fills between the aggregates can be completely excluded and blocks can be manufactured using only the aggregates, so the space between the aggregates is very wide and the permeability is dramatically improved.

This type of pitcher (23) filters out not only trash such as fallen leaves and cigarette butts, but also fine foreign substances (the cause of fine dust) accumulated on the sidewalk.

In addition, since the spaces between the aggregates are all connected, even if soil particles, etc. flow into the pores, they all flow downward when dried and the pores are naturally restored, so the water permeability lasts for many years.

The biopolymer concrete described above is an example of permeable concrete for forming the permeable portion (23) of the present invention, and permeable concrete of other compositions is also possible.

According to the structure of the cover (20) as described above, the entire cover (20) can be lifted and the working port (21) can be opened and closed by only opening and closing the cover portion (22), which is very small and light compared to the cover (20), without opening the main body (10) of the storage tank, so that maintenance work is very easy, and the excellent water permeability of the water permeable portion (23) enables rapid rainwater permeation, thereby preventing flooding of the sidewalk.

The filter (30) filters foreign substances contained in rainwater flowing into the main body (10) of the storage tank. A normal filter can be used, and a filter made of the same material as the permeable portion (22) of the cover (20) can also be used. The rainwater drainage portion (13) is the optimal installation location, and the structure is designed to particularly increase filtration efficiency. It includes an insertion portion (31) inserted into the rainwater drainage portion (13) and a support portion (32) formed with a cross-sectional area larger than that of the insertion portion (31) and supported on the inner surface of the main body (10) of the storage tank. A handle (33) (ring shape, etc.) is connected to the support portion (32).

The filter (30) is cleaned by a vacuum suction method, etc., and replaced when excessively contaminated.

In addition, a filter support (34) is applied so that the filter (30) is inserted into the rainwater drainage part (13) and supported on the inner surface of the storage tank body (10) and so that the filter (30) can be easily maintained.

The filter support (34) is formed in a rod shape, plate shape, etc., and one side is supported on the wall opposite the rainwater drainage part (13) and the other side is supported on the support part (32) of the filter (30). That is, the filter (30) is supported by being pushed toward the rainwater drainage part (13) using the opposite wall as a support base.

The sidewalk-type infiltration storage facility of the present invention is capable of allowing rainwater discharged through the sidewalk-type infiltration storage tank (100) to infiltrate into the ground, but preferably, a permeable layer (200) is used to increase the permeability and retention capacity, and a perforated pipe (210) is applied to connect with an existing drainage facility.

The permeable layer (200) is formed in the ground next to the main body of the storage tank (10), i.e., in communication with the discharge side of the rainwater drainage part (13), and is composed of crushed stones, so that it can contain rainwater drained from the rainwater drainage part (13) and allow small amounts of rainwater to permeate into the ground.

In addition, as shown in Fig. 6, the perforated pipe (210) is installed to induce and drain rainwater inside the permeable layer (200). The sidewalk-type infiltration storage tank (100) is installed in a point shape, that is, installed along the sidewalk and road at a certain distance from each other, and the permeable layer (200) is constructed long along the sidewalk (road), and the perforated pipe (210) is buried in the permeable layer (200) to induce rainwater inside the permeable layer (200) into the inside and then induce and drain it along the internal flow path.

Here, an emergency drain pipe (220) may be included to prevent flooding of the sidewalk when the drainage capacity of the drainage pipe (210) is insufficient through connection with the existing sewer system.

The emergency drain pipe (220) is configured to drain rainwater inside the perforated pipe (210) into an existing drainage system, and is preferably configured to drain into a rainwater catch basin (300) installed at a certain distance from the roadside.

Accordingly, the emergency drain pipe (220) is connected on both sides to the perforated pipe (210) and the rainwater receiver (300) in the ground between the perforated pipe (210) and the rainwater receiver (300), and is installed with a downward slope toward the rainwater receiver (300) for non-powered drainage utilizing the height difference.

The rainwater catcher (300) connecting the emergency drain pipe (220) may be an existing drainage facility that is already installed and operated, or may be additionally installed for the purpose of the present invention, and is connected to a sewer pipe.

The construction method of the sidewalk-type infiltration retention facility according to the present invention is as follows.

1. Removal of blocks, curbs, and some of the sidewalk concrete (Fig. 7).

The sidewalk layer of the area for constructing the protective infiltration storage tank of the present invention is removed, and the curb stones connected to the roadway and a portion (1) of the roadway pavement are crushed and removed.

2. Soil removal.

Soil is removed to secure a space of sufficient depth and area to install a sidewalk-type infiltration storage tank (100). The space is a space of a size where a permeable layer (200) and a perforated pipe (210) can be installed.

3. Installation of a pressurized infiltration storage facility (Fig. 8).

A non-woven fabric (40) is laid on the floor of the underground space, and a sidewalk-type infiltration storage tank (100) is inserted and installed on top of the non-woven fabric (60). The sidewalk-type infiltration storage tank (100) can be installed as a single insertion operation in a state where the storage tank body (10), etc., is already assembled, or the process can be divided into insertion and installation of the storage tank body (10), installation of a filter (30), and installation of a cover (20).

The remaining space next to the side of the infiltration tank (100) is filled with crushed stone to a certain height, a perforated pipe (210) is installed, and then crushed stone is filled on top of the perforated pipe (210) to construct a permeable layer (200).

Connect the emergency drain pipe (220) to the perforated pipe (210) and the rainwater collector (300).

4. Installation of drainage boundary stones (Fig. 9).

A drainage boundary stone (50) is installed at a location corresponding to the road-side inflow portion (12) of a sidewalk-type infiltration storage tank (100), and the drainage boundary stone (50) includes a drainage hole (51) that communicates with the road-side inflow portion (12).

5. Packaging (Fig. 10).

Install blocks on the sidewalk and pave the road surface with paving material.

When explaining the rainwater drainage process according to the present invention, rainwater on the sidewalk passes through the permeable portion (23) of the cover (20) and flows into the main body (10) of the storage tank, and in this process, foreign substances contained in the rainwater are filtered out, so that only the filtered rainwater flows in. At the same time, rainwater on the road side flows into the main body (10) of the storage tank through the road side inflow portion (12).

Rainwater flowing into the main body of the storage tank (10) passes through the filter (30) and is drained into the permeable layer (200), and in this process, foreign substances contained in the rainwater are filtered through the filter (30).

Some of the filtered rainwater is contained in the permeable layer (40), and some of it infiltrates into the ground while others flow into the interior of the perforated pipe (210).

Rainwater that seeps into the ground supplies water to the surrounding trees, and some evaporates as it passes through the sidewalk.

Rainwater that flows into the inside of the perforated pipe (210) is guided and drained along the perforated pipe (210).

Meanwhile, when rainwater flowing into the drainage pipe (210) rises to the height of the emergency drainage pipe (220), it flows into the emergency drainage pipe (220) and flows along the emergency drainage pipe (220) to the rainwater catcher (300) and is drained.

To explain the maintenance method of the present invention, the cover part (22) of the cover (20) is held, the work tool (21) is opened, and the cleaning equipment is inserted into the main body (10) of the storage tank through the work tool (21) to suction and remove the waste accumulated in the main body (10) of the storage tank. At this time, foreign substances remaining in the filter (30) are also suctioned and removed to restore the filter (30) to its initial state and reuse it.

10: Reservoir body, 11: Reservoir space
12: Road side inflow, 13: Rainwater drainage
20: Cover, 21: Work area
22: Cover part, 23: Pitcher part
24: Steel grating, 25: Biopolymer concrete
30: Filter, 31: Insert
32: Support, 40: Non-woven fabric
50: Drainage boundary stone, 100: Sidewalk-type infiltration storage tank
200: Pitcher layer, 210: Perforated pipe
220 : Emergency drain pipe,

Claims (9)

A sidewalk-type infiltration storage tank installed underground on the sidewalk to collect rainwater from the sidewalk and road and then drain it away;
A permeable layer is constructed along the above-mentioned sidewalk-type infiltration storage tank and permeates rainwater drained from the above-mentioned sidewalk-type infiltration storage tank into the ground, and,
It includes a perforated pipe buried in the permeable layer and inducing and draining rainwater inside the permeable layer.
The above-mentioned sidewalk-type infiltration storage tank is characterized by comprising a storage tank body having a storage space provided inside, a sidewalk-side inflow portion provided at the top, and a rainwater drainage portion formed at the bottom in the opposite direction to the sidewalk-side inflow portion, a cover installed at the sidewalk-side inflow portion of the storage tank body, a filter installed inside the storage tank body to filter rainwater and then drain it into the ground, and a filter support mounted at the bottom of the storage tank body, one side of which is supported on a wall surface of the storage tank body and the other side of which is supported by the filter to closely contact the filter with the storage tank body. A sidewalk-type infiltration retention facility according to claim 1, characterized in that it includes an emergency drain pipe that is arranged so as to slope downward toward the rainwater drain between the perforated pipe and the rainwater drain installed on the roadside, and is connected to the perforated pipe and the rainwater drain on both sides to drain rainwater in the perforated pipe to the rainwater drain. delete A sidewalk-type infiltration storage facility according to claim 1, characterized in that the cover is formed by a combination of a working port, a nonporous cover part that does not allow rainwater to pass through when opening and closing the working port, and a permeable part that allows rainwater to flow into the inside of the storage tank body through an internal passage. A sidewalk-type infiltration retention facility according to claim 4, characterized in that the cover comprises a lattice-shaped steel grating, an opening formed by removing a portion of the steel grating, a nonporous cover forming the cover by opening and closing the opening, and a permeable portion formed by laying biopolymer concrete on the steel grating. A sidewalk-type infiltration storage facility according to claim 1, characterized in that the filter includes an insertion part inserted into the rainwater drainage part and a support part formed with a cross-sectional area larger than the insertion part and supported on the inner surface of the main body of the storage tank.
delete A main body of a storage tank having a sidewalk inflow port at the top and a rainwater drainage port formed in the opposite direction to the sidewalk inflow port at the bottom while a storage space is provided inside;
A cover installed on the inlet side of the main body of the above storage tank;
A filter installed inside the main body of the above storage tank to filter rainwater and then drain it into the ground;
A filter supporter is provided on the bottom of the main body of the storage tank, one side of which is supported on the wall surface of the main body of the storage tank, and the other side of which is supported on the filter, thereby closely contacting the filter to the main body of the storage tank.
A sidewalk-type infiltration storage tank characterized in that the cover is composed of a combination of a working port, a nonporous cover part that prevents rainwater from passing through when the working port is opened and closed, and a permeable part that allows rainwater to flow into the inside of the storage tank body through an internal passage. A method for constructing a pressurized infiltration retention facility according to claim 1,
Phase 1 involves removing some of the pavement, curbs and road pavement;
The second stage involves removing the soil beneath the pavement to create space underground;
A third step of installing the above-mentioned infiltration storage tank in the space secured in the above-mentioned second step;
A method for constructing a sidewalk-type infiltration storage facility, characterized by including a fourth step of forming a permeable layer next to the sidewalk-type infiltration storage tank and installing a perforated pipe within the permeable layer.

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