KR20130011512A - Apparatus for water supply education simulator - Google Patents

Abstract

PURPOSE: A simulation water supply apparatus for education is provided to improve operation capability of a water supply apparatus by experiencing an operation state by directly setting up various operation states. CONSTITUTION: A water tank(100) is equipped in indoor. The water tank receives water through a first pipe(110). A pressure pump unit(200) is connected to a second pipe supplying the stored water. The pressure pump unit transfers the supplied water. A collecting tank(300) is connected to the pressure pump.

Description

Educational simulation water supply device {Apparatus for water supply education simulator}

The present invention relates to a water supply device, and more particularly, to a training simulation water supply device that enables a plurality of trainees to easily carry out various simulations through a water collecting and reservoir facility provided indoors and to train the same.

Generally, a water collecting well for treating groundwater and rainwater is used in an underground machine room of a large-scale building such as an apartment, and the water collecting well is used to collect and collect rainwater and groundwater at the construction site when the construction is in progress. After finishing, it collects the collected water until it is pumped out. That is, it is used to store rainwater or groundwater introduced into the ground floor of a building by using a collecting well having a predetermined size and to discharge it to a sewage treatment facility through a sewage pipe using a pump.

A water tank is provided in the building to temporarily store water consumed in the building together with the sump, and the water tank is used for storing water having various purposes for storing emergency water and fire fighting water. The reservoir is installed on the basement or ground level of the building, or the elevated water tank is installed on the roof or water tower of the building. If the building is a high-rise building, an intermediate tank is installed at the middle floor of the building.

A reservoir generally used in the related art will be described with reference to the drawings.

Referring to the accompanying FIG. 1, since the reservoir 10 is mostly made of a large stainless steel sheet having a large capacity and invisible inside, the manager who manages the reservoir also knows only the shape of the outside of the reservoir. It was difficult to grasp the concrete structure unless it was entered directly.

With the conventional water tank used as described above, there is a problem that novice technicians or trainees can easily grasp the configuration and overall operation of the water supply system of the building.

This reduces the unnecessary time and effort required by novice technicians and trainees to use the partial knowledge and information as a whole to understand the configuration and principle of operation of the water supply system, and facilitates the configuration, operation principle and efficient operation of the water supply system. The necessity of contacting and providing education at the same time emerged.

Embodiments of the present invention are to reduce the size and set of the water supply device installed in a building or industrial site, so that a number of early technicians or trainees more easily grasp the operation principle and structure of the water supply device, and to provide training and practice for the actual building In addition, it aims to understand the water supply equipment installed at the industrial site and thereby to operate the water supply equipment installed at the site efficiently.

According to an aspect of the present invention, the first front surface is made of a transparent material so that the room is provided in the room and supplied with water at room temperature through the first pipe for education of the operating principle of the water supply system and the inner region is visible on the front surface. Reservoir with plate; A pressurizing pump unit connected to a second pipe through which water stored in the water storage tank is supplied, and pressurizing and supplying water supplied at a predetermined discharge pressure; And a water collecting well having a second front plate made of a transparent material connected to the pressure pump unit and the third pipe through which the water transferred from the pressure pump unit is stored and discharged, and the inner region is visible on the front surface thereof. .

The reservoir includes a first valve provided in the first pipe; And a water level detector inserted into the reservoir and transmitting a signal to the first valve according to the flow rate of the water introduced through the first valve to adjust the amount of water introduced into the reservoir.

The water level sensing unit includes a plurality of electrodes extending in different lengths toward the lower side of the reservoir.

The reservoir further includes a first drain pipe for draining water introduced through the first pipe.

The first front panel further includes a display unit for visually recognizing the water level introduced into the reservoir, wherein the display unit includes a low water level display unit displayed at a height corresponding to a low water level, a high water level display unit displayed at a height corresponding to a high water level, And a pressure pump start and stop display unit displaying the start and stop positions of the pressure pump unit.

The pressure pump unit includes a plurality of booster pumps connected in series with the second pipe; A pressure sensor for sensing the pressure of the second to third pipes; And a check valve provided at the third pipe and disposed at a rear end of the booster pump.

The sump well further includes a drain pump for pumping the water supplied through the third pipe to the drain.

The drain pump further includes a plurality of plotters provided inside the sump, and the position of which is varied according to the water level inside the sump.

The educational simulation water supply device includes a control unit for controlling the operating state of the pressure pump unit receives water level information of the reservoir and the sump.

Embodiments of the present invention, through the education of the overall configuration and operating principle for the water supply device can be carried out by a plurality of trainees at the same time the technology training combined with theory and practice to maximize the educational effect and the knowledge acquired through the field Can be directly grafted to the water supply provided in the.

Embodiments of the present invention can directly set the various operating conditions of the water supply device, and can directly experience the operating state according to it can improve the operating capacity of the water supply device.

Embodiments of the present invention can be carried out using a water supply reduced in size without dismantling the complex water supply installed in the actual building.

1 is a perspective view showing a conventional reservoir.
2 is a view showing the configuration of a training simulation water supply apparatus according to an embodiment of the present invention.
Figure 3 is a view showing a reservoir provided in the training simulation water supply apparatus according to an embodiment of the present invention.
Figure 4 is a view showing a state in which the water well and the reservoir provided in the training simulation water supply device according to an embodiment of the present invention is actually installed.
Figure 5 is a block diagram showing a control unit and a configuration connected to the control unit provided in the educational simulation water supply apparatus according to an embodiment of the present invention.
6 to 7 is a view showing a state in which the actual pressure pump unit provided in the training simulation water supply apparatus according to an embodiment of the present invention.
8 is a view showing a state in which the water collecting well actually provided in the training simulation water supply apparatus according to an embodiment of the present invention.
9 to 11 is a state diagram using the educational simulation water supply apparatus according to an embodiment of the present invention.

With reference to the drawings for the configuration of the educational simulation water supply apparatus according to an embodiment of the present invention. For reference, Figure 2 is a view showing the configuration of the educational simulation water supply apparatus according to an embodiment of the present invention, Figure 3 is a view showing a reservoir provided in the educational simulation water supply apparatus according to an embodiment of the present invention.

2 to 3, the training simulation water supply device 1 may be installed in a classroom (not shown) provided in the room, and the total length is 10m or less in length so as to be installed in the classroom. The height and the height corresponding to the eye height of the trainees can facilitate understanding of the trainees' visibility and operating state.

The water supply device 1 is provided with a reservoir 100 which is provided indoors and stores water at room temperature supplied through the first pipe 110 to educate the operation principle of the water supply system. A pressure pump unit 200 connected through a second pipe 210 is provided, and includes a sump well 300 connected through the pressure pump unit 200 and the third pipe 310.

Reservoir 100 is a kind of water tank in which the constant introduced through the first pipe 110 is stored, so that a plurality of trainees can easily grasp the supply state of the water introduced into the reservoir 100. The first front plate 120 that can directly see the inner region of the) is provided on the front of the reservoir (100). The first front plate 120 may use a transparent acrylic plate or a tempered glass having a predetermined thickness, and other materials except for the acrylic plate and the tempered glass may be used.

The reservoir 100 is formed in a rectangular shape and a separate waterproof treatment may be made inside and outside to prevent leakage of water introduced through the first pipe 110, or a sealing material (not shown) may be used. The reservoir 100 is provided with a first valve 102 on the movement path of the first pipe 110, the first valve 102 is adjusted the supply amount according to the amount of water stored in the reservoir (100).

The reservoir 100 is provided with a water level detection unit 102 for detecting the amount of water introduced into the interior, the water level detection unit 102 is a plurality of electrode rods extending to different lengths toward the lower side of the reservoir 100 Is done. The water level detector 102 includes a first electrode having the longest length, a second electrode having the shortest length, and an nth electrode having different lengths between the first and second electrodes. The first to n-th electrodes transmit electrical signals generated by contact with water to the controller 400 (see FIG. 8), and the controller 400 transmits a control signal to the first valve 102 according to the input signal. The amount of water introduced through the first pipe 110 is adjusted differently according to the amount of water stored in the reservoir 100 through the transmission to adjust the opening amount of the first pipe 110.

Reservoir 100 includes a display unit 122 that can visually recognize the water level introduced into the first front plate 120, the trainees to see and recognize the display unit 122 with the eyes directly and the reservoir ( Simulation of the operating state of the pressure pump unit 200 and the sump well 300 according to the water level of 100 may be performed.

The display unit 122 includes a low water level display unit 122a displayed at a height corresponding to a low water level, a high water level display unit 122b displayed at a height corresponding to a high water level, and a pressurized pump start and stop position of the pressurized pump unit 200. Stop display portions 122c and 122d. The display unit 122 may be displayed in different colors, and in particular, the low water level display unit 122a and the high water level display unit 122b may be displayed in red, thereby improving visual recognition to trainees. Reservoir 100 is provided with a plurality of balls (floating) floating on the water surface, by the ball is more visual recognition according to the level change. For example, when the water drops or rises due to the water introduced into the reservoir 100, as the balls descend or rise together, the education effect of trainees according to the fluctuations in the water surface may be improved. The balls may be made of different colors and are not particularly limited in number.

The reservoir 100 is connected to one side of the first drain pipe 101 for overflowing the water introduced through the first pipe 110, and is provided with water that is excessively supplied through the first pipe 101. Through a closed floor drain (not shown).

The reservoir 100 is provided with a drain pipe 103 for draining a large amount of water introduced into the reservoir 100 separately from the first drain pipe 101, and the reservoir 100 through the drain pipe 103. All the water stored in can be drained.

3 to 4, the reservoir 100 is spaced apart from the bottom with a predetermined height or seated on an upper surface of the supporting part 100a provided separately, and the supporting part 100a is formed of a concrete structure or steel. Like a frame, a material or a material in which deformation does not occur due to the weight of the reservoir 100 is used.

A pressurized pump unit according to an embodiment of the present invention will be described with reference to the drawings. For reference, Figures 6 to 7 are views showing a state in which the pressure pump unit provided in the educational simulation water supply apparatus according to an embodiment of the present invention is actually installed.

6 to 7, the pressure pump unit 200 includes a booster pump 202 connected to the second pipe 210 and a pressure sensor for detecting pressure of the second to third pipes 210 and 310. And a check valve 230 provided at the third pipe 310 and disposed at a rear end of the booster pump 202 to supply water supplied from the reservoir 100 through the second pipe 210. It is provided to supply at a predetermined discharge pressure.

The pressure sensor 220 is installed on the first pressure sensor 220a provided in front of the pressure pump unit 200 and the third pipe 310 to sense the pressure of the water pressurized by the pressure pump unit 200. The second pressure sensor 220b is included.

Pressurized pump unit 200 is provided for water supply in a high-rise building consisting of a plurality of layers and used to supply water to the high water tank provided in the high-rise building, in this embodiment instead of supplying water to the high water tank It is provided to supply water to the 100 and the sump (300).

The booster pump 202 is composed of the first booster pump 202a and the second booster pump 202b, and the discharge pressure is set to a specific pressure. In this embodiment, the booster pump 202 is set to 3 kg / cm ² but is not necessarily limited to the pressure. .

The check valve 230 is installed in a connection pipe connected to the first booster pump 202a and the second booster pump 202b, respectively, and the water pressurized through the first to second booster pumps 202a and 202b Prevent backflow from the piping 310 to the booster pump 202.

The pressure sensor 220 includes a first pressure sensor 220a installed in the second pipe 210 and a second pressure sensor 202b installed in the third pipe 310. The first pressure sensor 220a senses the shear pressure of the booster pump 202 and the second pressure sensor 202b detects the pressure when the water pressurized by the booster pump 202 is moved through the third pipe 310. Detects and transmits it to the control unit 400. A more detailed description of the pressure sensor 220 and the control unit 400 will be described later.

A water collecting well according to an embodiment of the present invention will be described with reference to the drawings. For reference, FIGS. 4 and 7 are views illustrating a state in which a water collecting well provided in an educational simulation water supply device according to an embodiment of the present invention is actually installed.

Referring to FIG. 2 or FIG. 4 and FIG. 7, the water collecting well 300 is a water tank in which a large amount of water supplied through the third pipe 310 is stored. The second front plate 230 is provided at the front side to visually recognize the water flowing into the inside and the inner region. The second front plate 320 may use a transparent acrylic plate or a tempered glass having a predetermined thickness, and other materials except for the acrylic plate and the tempered glass may be used.

The water collecting well 300 is formed in a rectangular shape and is separately waterproofed inside and outside to prevent leakage of water introduced through the third pipe 310. Sumping chamber 300 is provided with a plurality of balls (floating) floating in the water surface, by the ball is more visual recognition according to the level change. For example, when the water drops or rises due to water introduced into the sump 300, as the balls descend or rise together, the education effect of trainees due to fluctuations in the water surface may be improved. The balls may be made of different colors and are not particularly limited in number.

In the sump well 300, a second drain pipe 301 is connected to the upper portion so that water introduced through the third pipe 310 overflows, and water excessively supplied through the second drain pipe 301 is separately provided. Discharged to the provided bottom drain (not shown).

The sump well 300 is provided with a drain pipe 303 for draining a large amount of water introduced into the sump well 300 separately from the second drain pipe 301, and the sump well through the drain pipe 303. All the water stored in the 100 can be drained.

Sump 300 is seated on the upper surface of the base portion 300a having a predetermined height from the bottom, the base portion 300a is deformed by the weight of the sump 100, such as a concrete structure or steel frame Unused materials or materials are used.

The sump well 300 is provided with a drain pump 330 therein for pumping the water supplied through the third supply pipe 310 to the drain hole, and the drain pump 330 includes first to second drain pumps 331 and 332. Consists of a plotter 333 is changed in position according to the water level inside the sump 300 for the operation of the drain pump 330. The plotter 333 includes a plotter ball 333a having a spherical shape, and the plotter ball 333a transmits different signals according to the surface height to the controller 400 while floating according to the surface height, and the controller 4400. The control unit transmits a control signal to the drain pump 330 according to the input signal to control the operation state.

A control unit according to an embodiment of the present invention and a peripheral configuration associated with the control unit will be described with reference to the drawings.

Referring to FIG. 5, the controller 400 may control an overall operating state of the educational water supply device 1, and is connected to the computer 600 to perform various operations that have not been practiced in a water supply device installed in an actual building. You can easily test your hands on the mode. The trainees can directly check the operating state of the reservoir 100 and the sump well 300 while driving a separate simulation program using a computer.

The input panel 500 includes a plurality of buttons and levers (not shown) required for the operation of the reservoir 100 and the sump 300 in front of the rectangular panel so that the trainees can directly perform the operation state of the water supply device. ) Is provided, a signal according to the on and off of the button and the lever is transmitted to the control unit 400, and the control unit 400 controls the operating states of the booster pump 202 and the drain pump 330 according to the input signal. To control.

In addition, the controller 400 may receive a signal from the water level detector 120, the pressure sensor 220, and the plotter 333 to control an operation state of the booster pump 202 and the first valve 102.

The use state of the educational simulation water supply apparatus according to an embodiment of the present invention configured as described above will be described with reference to the drawings. Prior to the description, for more effective simulation of the water supply system, it is possible to perform the simulation with all the water stored in the reservoir and the sump drained, or to perform the simulation with a certain amount of filled water. Therefore, the simulation can be performed by selecting any one state.

5 or 9, the trainees operate the buttons provided on the computer 600 or the input panel 500 to supply water to the reservoir 100 through the first pipe 110. The sensing rod provided in the water level detecting unit 120 transmits a detection signal according to the water level of the water tank 100 to the control unit 400, and the control unit 400 currently uses a first valve according to the water level of the water tank 100. The amount of water supplied to the reservoir 100 through the first pipe 110 is adjusted by adjusting the opening amount of the 102. For example, when the water level of the reservoir 100 detected by the current water level detection unit 120 is detected as the surface where the low water level display unit 122a is located, the control unit 400 is currently in a low water level state. The control signal is transmitted to the first valve 102 such that the opening degree of the first valve 102 is opened at 100%. The opening amount is adjusted to 100% state by the signal transmitted from the control unit 400, and a large amount of water is introduced into the reservoir 100 through the first pipe 110.

The control unit 400 controls the opening amount of the first valve 102 differently for a predetermined time according to a signal detected by the water level detecting unit 120, and the trainees the water level is reduced by the water flowing into the reservoir 100 The changing state can be visually recognized through the front plate 102 and at the same time can be more accurately recognized through the change in the position of the ball floating along the water surface.

10 to 11, the trainees may input the input panel 500 or the computer 600 so that the water surface is maintained at the position where the pressure pump start indicator 122c is displayed to check the operation state of the pressure pump unit 200. Adjust the amount of water flowing into the reservoir (100) through.

When the surface of the water where the water storage tank 100 is held in the position of the pressure pump start-up display unit (122c), the first to the second booster pump (202a, 202b) at the same time, the second pipe at a pressure of group 3kg / cm ² is set as work ( Pressurized water introduced through the 210 is supplied to the third pipe 310. The control unit 400 compares the currents of the first and second booster pumps 202a and 202b with respect to the pressures of the first and second booster pumps 202a and 202b through signals input through the first to second pressure sensors 202a and 202b, respectively. It is determined whether water is supplied to the sump well 300 through the third pipe 310. Trainees can observe the operating state of the first to second booster pumps (202a, 202b) and check the water discharged to the sump 300 directly through the second front plate 320, the sump Through the ball located above the water surface of the 300 can be recognized more accurately. The first to second booster pumps 202a and 202b suck water at a predetermined pressure through the second pipe 210 to pump the third pipe 310 and are pumped into the third pipe 310. Water is supplied through the check valve 330 to the sump well 300 without being flowed back toward the first to second booster pumps 202a and 202b.

When the first to second booster pumps 202a and 202b are operated for a predetermined time, the water tank 100 may have a water level lowered while the water stored in the water tank 100 is continuously transferred to the pressure pump unit 200. The opening degree of the first valve 102 is controlled by the controller 400 according to the detection signal sensed by the detector 120, and water is supplied to the reservoir 100 again at the position of the pressurized pump stop display 122d. When the water surface is maintained, the operation of the booster pump 202 is switched off and no more water is supplied from the reservoir 100 to the pressure pump unit 200. When the water surface of the reservoir 100 is maintained at the position of the high water level display 122b, the first valve 102 is controlled to be in a closed state so that no more water is supplied into the reservoir 100.

The trainees can visually check and recognize the process of the pressurized water from the first to second booster pumps 202a and 202b flowing into and into the sump 300 through the third pipe 310. ) Can be seen at a glance the water flow path.

In addition, the trainees can confirm that the position of the plotter ball 333a is increased according to the flow rate supplied to the sump well 300, and the control unit 400 according to the position of the controller 400 according to the rise of the plotter ball 333a. The signal is transmitted to the control unit 400 receives the input and controls the operation of the first to second drain pump (331,332) in the on state.

The first to second drain pumps 331 and 332 may pump water stored in the sump 300 to supply water to the second drain pipe 301, and may be actually supplied to households living in each floor, but the present embodiment In the description to be drained through a drain (not shown).

Trainees can grasp the operating state of the plotter 333 provided therein through the second front plate 320 with respect to the sump 300 and the operating state of the drain pump 330 according to the operation of the plotter 333. At the same time can be grasped.

Trainees operate over the water supply device 1 by simulating a state in which water supplied to the reservoir 100 is pumped and supplied through the reservoir 100, the pressure pump unit 200, and the sump well 300. Observe and experience the condition directly.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100: reservoir
110: first pipe
120: first front panel
200: pressurized pump unit
202: Booster Pump
220: pressure sensor
230: check valve
210: second pipe
300: sump
310: third pipe
330: drain pump
333: Plotter
400:

Claims (9)

A storage tank provided indoors and having water stored at room temperature through a first pipe for education of the principle of operation of the water supply system, and having a first front plate made of a transparent material so that an inner region can be seen in front;
A pressurizing pump unit connected to a second pipe through which water stored in the water storage tank is supplied, and pressurizing and supplying water supplied at a predetermined discharge pressure; And
Educational reservoir connected to the pressure pump unit and the third pipe, and the water collection well is provided with a second front plate made of a transparent material so that the water transferred from the pressure pump unit is stored and discharged and the inner region is visible on the front surface. Simulation water supply device. The method according to claim 1,
The reservoir is
A first valve provided in the first pipe;
And a water level sensor inserted into the reservoir and transmitting a signal to each other according to the flow rate of water introduced through the first valve to adjust the amount of water introduced into the reservoir. The method of claim 2,
The water level detection unit,
Educational simulation water supply device comprising a plurality of electrodes extending in different lengths toward the lower side of the reservoir. The method according to claim 1,
The reservoir is
Educational simulation water supply device further comprises a first drain pipe for draining the water introduced through the first pipe. The method according to claim 1,
The first front panel,
It further includes a display unit for visually recognizing the water level introduced into the reservoir,
The display unit includes:
An educational simulation water supply device including a low water level display unit displayed at a height corresponding to a low water level, a high water level display unit displayed at a height corresponding to a high water level, and a pressurized pump start and stop display unit displaying the start and stop positions of the pressure pump unit. The method according to claim 1,
The pressure pump unit,
A plurality of booster pumps connected in series with the second pipe;
A pressure sensor for sensing the pressure of the second to third pipes;
Educational simulation water supply device comprising a check valve provided in the third pipe and disposed in the rear end of the booster pump. The method according to claim 1,
The catchment well,
Educational simulation water supply device further comprises a drain pump for pumping the water supplied through the third pipe to the drain. The method of claim 7, wherein
The drain pump,
A plurality of the water supply is provided in the sump, the simulation simulation water supply device further comprises a plotter whose position is changed in accordance with the water level inside the sump. The method according to claim 1,
The educational simulation water supply device,
Educational simulation water supply device including a control unit for receiving the water level information of the reservoir and the sump to control the operating state of the pressure pump unit.

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