KR101674202B1 - Automatic control system of constant flow considering in apartment com-plex - Google Patents

Abstract

An automatic control system for the static flow of each apartment in the apartment is introduced, which is proportional to the total flow of the apartment house in proportion to the heating status of each household. The automatic control system for the constant flow reduces the total flow of the apartment by the flow rate corresponding to the reduced generation of the heating, which reduces the unnecessary use of the pump in proportion to the reduced flow rate of the heating and prevents the noise caused by the flow rate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic control system for a constant-

The present invention relates to a constant flow automatic control device, and more particularly, to a static flow automatic control device for a dwelling house in which a total flow rate of a dwelling house is proportionally actively controlled in accordance with a heating state for each household.

Generally, a heating system is a system in which individual heating is performed by heating a fluid by a heat source such as a boiler independently installed in each generation, and heating is performed by an external heat source installed outside the household, It is distinguished by collective heating, which is supplied by each household, and the group heating is divided into central heating using a heat source such as a central housing boiler in a public housing complex or a large apartment house, and a heat source such as a power plant outside a public housing complex District heating is distinguished.

Particularly, as shown in FIG. 1, the district heating generates a medium-temperature water required for heating and hot water supply in a power plant, and supplies it to an object of heat supply such as an apartment, a house, a shopping center, an office, a school, a hospital, In the collective energy supply system, the steam turbine generator is operated by using the steam generated from the heat exclusive boiler of the power plant (A), and the middle temperature water (80 to 120 ° C) is produced by using the waste heat generated from the steam turbine generator, The produced heavy water is transported and recovered to the heat exchanger 2 of the object B to be heat-treated through the heat transfer pipe 1. The heat source of the mesophilic water transported through the heat transfer pipe (1) is used for heating and hot water supply of the object (B) for heat supply while heat is exchanged with the central supply pipe of the heat supply object (B).

As shown in FIG. 2, a tandem heating system of a dwelling unit such as an apartment includes a central supply pipe 10 in which heat is exchanged in an external heat exchanger 2, A hot water pipe 12a branched from the stratified hot water pipe 11 so as to supply the water for each household of each layer and a hot water pipe 12b heat exchanged in the hot water pipe 12a, A central water return pipe 20 in which the stratified water return pipe 13 is converged and connected to the central supply pipe 10 and a central water return pipe 20 for guiding the flow of hot water to the central water return pipe 20, (14). At this time, a flow regulating valve (21) for regulating the maximum flow rate flowing into the generation of each layer is installed in the layered water return pipe (13).

That is, when the heat source transported through the external heat transfer pipe 1 performs heat exchange with the central supply pipe 10 through the heat exchanger 2, the hot water in the central supply pipe 10 flows through the hot water pipe 11 The hot water in the hot water duct 12a is heat-exchanged with the surroundings to heat the room, living room, etc. of the household. The hot water whose temperature has been lowered is collected in the central water return pipe 20 through the layered water return pipes 13 of the respective layers and then flows into the heat exchanger 2 while being exchanged with the central supply pipe 10, Lt; / RTI >

However, in the above-mentioned conventional tandem heating system, since the total flow rate for heating the apartment is preliminarily set during the construction, the pump maintains a constant motor rotation number and the predetermined amount of refinery flows in the central supply pipe. The power of the pump can not be reduced even if it is used in a small amount, and a problem occurs such that a flow more than the amount set to flow originally flows through a stratified hot water pipe at a higher flow rate and noise is generated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a heating system for heating a room without heating in a household, The present invention provides an automatic control device for a constant flow rate in a dwelling house that reduces the use of a pump and prevents noise from being generated due to overflow.

In order to solve the above-mentioned problems, the present invention provides a refrigerator including a central supply pipe, a hot water pipe for each floor, a control unit for each household, a floor water return pipe, a pressure differential pressure regulating valve for each floor, a central water return pipe, a pump unit and a central control unit, The hot water pipes are branched to the central supply pipe to supply hot water to the households of the respective floors and the control unit for each household is supplied with the flow rate And the layer-by-layer differential pressure regulating valve is installed in the layered water returning pipe to regulate the flow rate of the layered water returning pipe by an electrical signal, and the central returning pipe adjusts the flow rate of the layer- The flow rate of the circulated water is converged and supplied to the central supply pipe, and the pump unit is installed in the central water supply pipe, And the central control unit receives the flow rate signal from the control unit for each generation to control the pump unit and the differential pressure control valve for each layer, Thereby controlling the total flow rate supplied through the central supply pipe and adjusting the flow rate of the pressure difference flow control valve for each layer by the flow rate corresponding to each layer generation.

Preferably, the present invention further includes a dynamic pressure regulating valve installed in the central water return pipe for correcting the total flow rate regulated by the pump unit by an electrical signal, The flow rate is precisely controlled by the above-mentioned pressure difference control valve.

Preferably, the present invention further includes a supply connection pipe communicating with a central supply pipe provided in each of the different apartment houses, and a water exchange connection pipe communicating with a central exchange pipe installed in each of the different apartment houses, The number of revolutions of the motor of the pump unit is reduced by the amount of flow reduced by the control of the control unit for each household installed in the apartment house to control the total flow rate supplied to the different apartments through the central supply pipe.

Preferably, the central control unit stores the optimal flow rate value proportional to the required heat quantity of the household in consideration of the heating load for each household, and calculates the optimum flow rate value of the generation controlled by the generation- And the flow rate of the layer-by-layer differential pressure regulating valve is decreased according to the ratio of the optimum flow rate of the bed.

Preferably, the heating load for each household stored in the central control unit is calculated by adding all of "heat conduction rate x area x azimuth difference x temperature difference" of each surface constituting one room in each generation of each floor according to the number of rooms.

According to the present invention, the following remarkable effects can be realized.

First, according to the present invention, since the total flow rate of the apartment house is actively controlled in proportion to the heating state of each household, unnecessary use of the pump can be reduced, and noise caused by the flow rate can be prevented.

Second, the present invention is advantageous in that, when the total flow rate is automatically reduced in response to a generation in which heating is reduced, the flow rate is reduced by a flow rate that satisfies the required heat quantity of the household, so that the optimal heating state can be maintained at all times.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing a general district heating system,
FIG. 2 is a schematic view showing a conventional heating system of a dwelling house according to the prior art,
3 is a block diagram of an apparatus for automatically controlling a constant flow rate in a dwelling house according to an embodiment of the present invention.
4 is a cross-sectional view showing the structure of the layer-by-layer differential pressure regulating valve used in the embodiment of the present invention,
5 is a sectional view showing a structure of a driving body used in the present invention,
6 is a block diagram of an apparatus for automatically controlling the flow rate of a dwelling unit according to another embodiment of the present invention.

In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 3, the automatic flow rate control apparatus according to the present invention reduces the total amount of flow by the amount of flow corresponding to a reduced generation of heating, reduces the use of unnecessary pumps in proportion to the reduced flow rate of heating, Thereby preventing noise from being generated.

In order to realize this, the automatic flow control apparatus includes a central supply pipe 10, a stratified hot water pipe 110, a generation control unit 120, a floor water return pipe 130, a floor pressure differential control valve 200, (20), a pump unit (140), and a central control unit (150).

Specifically, the stratified hot water pipe 110 is configured to supply hot water for each generation of each stratum, and the hot water pipe 121 of each household communicates with the stratified hot water pipe 110 to branch each room, Ensure heat exchange with the room. At this time, the flow rate flowing through the hot water line 121 is controlled through the control unit 120 for each generation. The control unit 120 for each generation uses the values input according to the characteristics of the respective loads. When the specific room is closed, accurate flow data is sent to the central control unit 150.

The control unit 120 controls the flow rate of the water supplied from the stratified hot water pipe 110 to the household through the driver. The driver controls the opening and closing of the passage of the hot water pipe 121 by the electric signal of the control unit 120 for each household When the driver opens the hot water duct 121, hot water can flow to the household, and when the heater closes the hot water duct 121, the heating is stopped because the hot water does not flow to the household.

The control unit 120 can receive information required for heating control from a temperature control unit (not shown) that can individually set a desired temperature in the room. At this time, The current temperature is applied to the control unit 120 for each household to enable heating control through the control unit 120 for each household.

In other words, the generation-specific control unit 120 compares the input desired temperature with the current temperature, and when the current temperature is lower than the desired temperature, the control unit 120 gives an on signal to the driver to open the corresponding hot water duct 121, When the heating is stopped due to the same temperature as the present temperature, an off signal is given to the driver so that the hot water duct 121 of the room is closed.

In addition, the control unit 120 for each generation applies the flow rate data flowing into the generation of each layer to the central control unit 150 through the opening / closing degree of a driver or a separate flow rate sensor.

The hot water that has been heat-exchanged in each layer generation is returned to the layered water return pipe 130 through the water return pipe 122 communicated with the hot water duct 121. At this time, a layer-by-layer differential pressure regulating valve 200 for regulating the flow rate of the layer-by-layer water return pipe 130 is installed in the layered water return pipe 130 by an electrical signal of the central control unit 150. The detailed description of the layer-by-layer differential pressure regulating valve 200 will be described later.

The flow rate recovered through the layer-by-layer water return pipe 130 of each layer is converged by the central water return pipe 20 and then supplied to the central supply pipe 10 through a heat exchange process by the heat exchanger 2.

On the other hand, the central control unit 150 receives the signal of the control unit 120 for each household, and controls the motor rotation speed of the pump unit 140 and the flow rate of the layer-by-layer differential pressure control valve 200 based on the signals.

In other words, the central control unit 150 reduces the number of revolutions of the pump unit 140 by the amount of flow reduced by the control of the control unit 120 for each generation in each layer generation, Adjust the flow rate. The central control unit 150 reduces the flow rate of the layer-by-layer differential pressure regulating valve 200 by the flow rate corresponding to each layer of the apartment house, and the amount of refining by each layer passing through the layer- It is equal to the sum of the flow rate.

In addition, the central control unit 150 provides data on the total flow rate reduced through the reduction of the number of revolutions of the motor of the pump unit 140 to the power plant providing the district heating, so that the central control unit 150 can supply the heat to the heat exchanger 2 So that the delivered flow rate can be reduced.

In the central control unit 150, an optimum flow rate value proportional to the required heat quantity required for optimum heating of the household is incorporated in consideration of the heating load for each household.

The required calories required to heat each household can be obtained by adding up the number of rooms after determining the required calories of each room. At this time, it is common to think that the required heat quantity of each room will be proportional to the floor area. However, the proportion of the required heat quantity to the floor area is the theoretical one ignoring the heating load. Even if the area of the floor is the same, the required calorific value can be changed. Even a room with a small floor area may have a larger required heat requirement than a room with a larger floor area.

Therefore, when designing the heating system, the heating load of each room is calculated by taking into consideration all the heat losses such as the number of windows, the size of the room and the room, as well as consideration of the area of each floor in accordance with the design standard. The amount of heat is determined.

The equation for calculating the heating load for each room is as follows. Here, the introduced heating load variable is a basic variable that can be considered in each room, and a variable that may affect the heating load, such as the heat or time that is emitted from the household appliance or the human body, may be added.

L =? (K x A x N x? T) ------- (Equation 1)

L: Heating load K: Heat conduction rate [kcal / h · m ² · k)

A: Area N: Bearing coefficient

Δt: Equivalent temperature difference

The value of the heat conduction rate, which is one of the factors for obtaining the heating load in Equation (1), relates to the characteristics of the material constituting the room, and when the heat conduction rate is large, it means that the heat loss is large. For example, the heat conduction rate of the glass door is 4.73, which is higher than the heat conduction rate of 1.38. Therefore, it can be seen that the heat loss is larger in the glass door than in the wooden door. Normally, the rate of heat conduction can be found in accordance with Article 21 of the Rules for Facility Regulations, and the value can be found according to the material shown in the "Percentage of Heat Percentage Rate of Building Sites by Region".

In addition, the area value of the factor does not mean only the floor area of the corresponding room but refers to all the surface areas surrounding the room. Generally, since the room is a hexahedron, the values for the four walls, the ceiling, And the bearing coefficients of the factors take into account the difference of heat loss according to each bearing in consideration of the orientations of east, west, south and north. The comparative temperature difference means a temperature difference between the outer surface and the inner surface with respect to any one surface (e.g., wall surface) constituting the room. In the case of the outer wall, the heat loss is increased.

As described above, the heating load in one room can be obtained by adding all of "heat conduction rate x area × azimuth coefficient x equivalent temperature difference" of each surface constituting the room, and the heating load of each floor of each floor is calculated The heating load of the room can be obtained separately and all the heating loads obtained can be obtained.

When the heating load is calculated, this is the required heat quantity required to heat the room optimally. The required heat quantity can be obtained by the following equation (2).

Q = G 占 C 占? T ------- (Equation 2)

Q: Required heat capacity [kcal / h] G: Flow rate [lph]

C: Specific heat [kcal / kg ℃] △ T: Temperature change (Indoor supply temperature - Indoor water return temperature)

In the above equation (2), the specific heat is a constant value (the specific heat is 1 because hot water is used), and the temperature change value is a constant value since it must always be kept at 15 ° C in order to meet the design standard described in the prior art.

As a result, since the amount of heat and the amount of flow are in proportion to each other, the flow amount can be increased to increase the required amount of heat, and when the required amount of heat required for each step is determined, the optimum amount of flow for satisfying the required amount can also be set. The optimum flow rate value can be calculated. The optimal flow rate for each layer can be obtained by calculating the optimum flow rate of the room and adding the optimum flow rate values according to the number of rooms.

The optimum flow rate value for each generation of each layer is stored in the central control unit 150, which will be described later, and is used to control the flow rate of the layer-by-layer differential pressure flow control valve 200.

4, the layer-by-layer differential pressure regulating valve 200 for regulating the flow rate of the layer-by-layer water return pipe 130 is installed in the layer-by-layer water return pipe 130 by an electrical signal of the central control unit 150.

The layer-by-layer differential pressure regulating valve 200 is installed in the layered water return pipe 130 and changes the flow rate of the layered water return pipe 130 by an electrical signal of the central control unit 150, The amount of refining supplied to each layer is limited.

That is, when an electrical signal is applied to the layer-by-layer differential pressure regulating valve 200, the flow rate cross-sectional area of the layer-by-layer water return pipe 130 is adjusted to change the flow rate passing through the layer- 200 are generally composed of a body 210, a chamber 220, a diaphragm 230, a moving body 240, and an actuator 250.

The body 210 has an inlet 211 and an outlet 212 formed at one side of the body 210 and an outlet 212 through which the fluid flows out. Is communicated. A sheet 213 is formed in the body 210 between the inlet 211 and the outlet 212 to reduce the cross-sectional area of the passage. The fluid that has entered the body 210 through the inlet 211 passes through the seat 213 And exits through the outlet 212 to the outside.

The chamber 220 is a predetermined space formed at one side of the inside of the body 210 and the hydraulic passages 221 and 222 are formed in the chamber 220 such that the oil pressure on the inlet 211 side and the oil pressure on the seat 213 side respectively act . A first oil pressure passage 221 communicating with the inlet 211 side is formed in the chamber 220 even though the oil pressure on the inlet 211 side is applied and the oil pressure on the seat 213 side is communicated The second hydraulic passage 222 is formed. The chamber 220 is provided with a first hydraulic chamber 223 communicating with the first hydraulic passage 221 and a second hydraulic chamber 224 communicating with the second hydraulic passage 222 by the diaphragm 230 The block is separated.

The diaphragm 230 is installed in the chamber 220 so that the first hydraulic chamber 223 and the second hydraulic chamber 224 are separated from each other and the oil pressure on the inlet 211 side and the oil pressure on the seat 211 on both sides of the diaphragm 230 213) side oil pressure, respectively.

The movable body 240 is elastically installed to one side of the diaphragm 230 to adjust the cross sectional area passing from the seat 213 to the outlet 212 by the pressure difference in the chamber 220. The diaphragm 230, And is deformed due to the pressure difference of the chamber 220, the deformation force is applied to approach the seat 213 side. The movable body 240 includes a head portion 241, a stem portion 242 and an elastic member 243. The head portion 241 is coupled to the diaphragm 230. Since the stem portion 242 extends from the head portion 241 toward the seat 213 and adjusts the sectional area passing from the seat 213 toward the outlet 212 in accordance with the deformation of the diaphragm 230, The stem portion 242 is moved in accordance with the deformation of the seat portion 230 to increase or decrease the sectional area passing from the seat 213 toward the outlet portion 212 to lower or raise the hydraulic pressure on the seat 213 side.

The second hydraulic passage 222 communicating with the second hydraulic chamber 224 may be formed in the body 210 to communicate with the seat 213. In the present invention, 242). Accordingly, the second hydraulic chamber 224 communicates with the seat 213 side via the second hydraulic passage 222 formed in the stem portion 242. When the first hydraulic chamber 223 and the second hydraulic chamber 224 are in the same pressure state, the moving body 240 must be restored to the initial position. When the elastic body 243 moves to the moving body 240, (Not shown).

When a fluid having a predetermined oil pressure enters the body 210 and a fluid having a higher pressure higher than a certain moment is introduced into the body 210, the oil pressure on the inlet 211 side becomes higher than the oil pressure of the seat 213, The pressure of the first oil pressure chamber 223 becomes higher than the pressure of the second oil pressure chamber 224 communicated with the seat 213. This pressure difference causes the pressure of the first oil pressure chamber 223 to reach the second oil pressure chamber 224 The deformation of the diaphragm 230 causes the deformation of the diaphragm 230 toward the second hydraulic chamber 224 and the deformation of the diaphragm 230 pushes the movable body 240 toward the seat 213, The cross-sectional area through which the end passes from the seat 213 toward the outlet 212 is reduced.

When the sectional area passing from the seat 213 to the outlet 212 is reduced, the hydraulic pressure in the seat 213 gradually increases to finally become the same as the oil pressure on the inlet 211 side, The pressure of the first hydraulic chamber 223 and the pressure of the second hydraulic chamber 224 reach an equilibrium state and the moving body 240 is restored to its original position by the elastic force.

The chamber 220, the diaphragm 230 and the moving body 240 are configured such that the oil pressure on the side of the inlet 211 and the oil on the side of the seat 213 can always be kept the same. This is because the pressure on the side of the inlet 211 and the side of the seat 213 must be the same so that the sectional area of the flow rate passing from the inlet 211 side to the side of the seat 213 can be controlled and controlled to a desired flow rate accurately.

When the oil pressure on the inlet 211 side and the oil pressure on the seat 213 side are maintained in the same state, the flow rate of the air passing through the seat 213 by the actuator 250 is adjusted. The actuator 250 is disposed on the other side of the body 210 and adjusts the actual flow rate by adjusting the sectional area passing from the inlet 211 to the seat 213 by an electrical signal. The flow rate control can be performed by substantially controlling the cross-sectional area passing from the side of the seat 213 to the side of the seat 213. [

The actuator 250 includes a driving body 251 and a moving rod 252. The driving body 251 is electrically connected to a central control unit 110 to be described later and receives an electric signal from the central control unit 110 When you receive it, you convert it to mobility.

The moving force of the driving body 251 is transmitted to the moving rod 252 and the cross sectional area passing from the inlet 211 side to the sheet 213 side is adjusted by the length change due to the movement of the moving rod 252. The central control unit 150 is electrically connected to the driving motor 253 of the driving main body 251 to operate the driving motor 253. The driving motor 253 drives the driving gear 255 through the reduction gear 254 ).

The driving gear 255 is connected to the moving rod 252 so as to transmit power, though not shown, so that the moving rod 252 provides an external force for linear motion. At this time, the central control unit 150 can know the flow rate at which the central control unit 150 receives the information about the position of the moving rod 252, which is linearly moved, from the inlet 211 side to the seat 213 side, The driving gear 255 is connected to the sensor gear 257 via a connecting gear 253.

Accordingly, when the driving gear 255 rotates, the sensor gear 257 rotates in conjunction with the sensor gear 257. A generally known variable resistor 258 is built in the sensor gear 257, and the output value of the variable resistor 258 is centered The central control unit 150 receives the output value of the variable resistor 258 in real time and can recognize the amount of rotation of the driving gear 255, that is, the position of the moving rod 252.

The driving gear 255 can be rotated more than once, but the number of rotations is limited to less than one since the sensor gear 257 must be rotated in contact with the variable resistor 258. In view of this principle, It is preferable that an appropriate gear ratio be set between the gear 255 and the sensor gear 257. In the present invention, the rotation angle of the sensor gear 257 is limited to 270 degrees or less, the variable resistor 258 is installed within the rotation angle range of the sensor gear 257, and the moving distance of the moving rod 252 It is possible to estimate the flow rate by knowing the moving distance of the moving rod 252 by inputting various parameters such as the diameter of the sheet 213 and the like.

The moving rod 252 extends from the driving body 251 and receives a force from the driving body 251 in a state of being inserted into the body 210 to control the sectional area of the moving rod 252 entering the seat 213. In this case, The flow rate is controlled as the rod 252 adjusts the cross-sectional area of the sheet 213. At this time, it is preferable that the outer diameter of the moving rod 252 is set to a size corresponding to the inner diameter of the seat 213. If the moving rod 252 is completely fitted to the seat 213, no fluid can flow at all, Quot; 0 ".

Particularly, the control signal sent from the central control unit 150 to the layer-by-layer differential pressure regulating valve 200 is sent to the driving body 251 among the actuators 250 of the layer-by-layer differential pressure regulating valve 200, Various parameters such as the moving distance of the moving rod 252 and the diameter of the sheet 213 are inputted to the central control unit 150 so that the flow rate can be estimated according to the moving distance of the moving rod 252 do.

On the other hand, a central pressure-regulating valve 300 for regulating the entire flow rate regulated by the pump unit 140 may be installed in the central water-return pipe 20. The differential pressure control valve 300 accurately receives the electrical signal from the central control unit 150 to precisely control the flow rate of the pump unit 140 due to the decrease in the number of revolutions of the motor. The detailed configuration is the same as that of the above-described layer-by-layer differential pressure regulating valve 200, and a description thereof will be omitted.

As shown in FIG. 6, the automatic static flow control apparatus according to the present invention can be applied not only to a single apartment house but also to a plurality of apartment houses composed of apartments.

For example, the central supply pipe 10, the stratified hot water pipe 110, the generation control unit 120, the layered water return pipe 130, the layered differential pressure control valve 200, the central water return pipe 20, The central control unit 150 and the heat exchanger 2 as main housing units and the central supply pipe 10, the stratified hot water pipe 110, the generation control unit 120, the floor water return pipe 130, The central supply pipe 10 of the main unit housing is connected to the central supply pipe 10 of the sub-unit housing via the supply connection pipe 30, The central water return pipe 20 of the main apartment house is connected to the central water return pipe 20 of the sub-apartment house through the water return connection pipe 40.

Accordingly, when the control unit 120 for each household of the main apartment house and the sub-apartment house applies the flow rate data to the household control unit 150 of the main apartment house, the central control unit 150 controls the household- 120, and controls the total flow rate to be supplied to the main apartment house and the sub-apartment house through the motor rotation number of the pump unit 140 based on the signal, The flow rate of the layer-by-layer differential pressure regulating valve 200 is adjusted by the flow rate corresponding to the amount of flow of the layer-by-layer differential pressure regulating valve 200 to be equal to the flow sum of the generations of the main and sub- It can be done.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments. It is to be understood that the invention is not limited thereto.

10: central supply pipe 20: central return pipe
110: hot water pipe for floor 120: control unit for each household
121: Hot water pipe 122: Water pipe
130: floor water return pipe 140: pump unit
150:

Claims (5)

A central supply pipe (10) for heat exchange in the heat exchanger (2) so that hot water is supplied to each floor of the apartment house;
A stratified hot water pipe (110) branched to the central supply pipe (10) and supplied with hot water to each layer generation;
A generation control unit 120 for controlling a flow rate supplied to a generation through a driver;
A layered water return pipe 130 in which hot water heat-exchanged in the generation is returned;
A layer-by-layer differential pressure regulating valve (200) installed in the bed-type return pipe (130) and controlling the flow rate of the bed-type return pipe (130) by an electrical signal;
A central water return pipe (20) converging the flow rate of the water recovered through the layered water return pipe (130) and supplied to the central supply pipe (10);
A pump unit (140) installed in the central water return pipe (20) and adapted to regulate the motor rotational speed by another electrical signal; And
And a central control unit (150) for receiving the flow rate signal from the control unit (120) and controlling the pump unit (140) and the flow control valve (200)
The central control unit 150 reduces the number of revolutions of the pump unit 140 by the amount of flow reduced by control of the control unit 120 for each generation in each layer generation, And the flow rate of the layer-by-layer differential pressure regulating valve (200) is adjusted by the flow rate corresponding to each layer generation. The method according to claim 1,
Further comprising a dynamic pressure regulating valve (300) installed in the central water return pipe (20) for correcting the total flow regulated by the pump unit (140) by an electrical signal,
Wherein the central control unit (150) precisely controls the total flow rate controlled by the pump unit (140) by the differential pressure control valve (300). The method according to claim 1,
Further comprising a supply connection pipe (30) communicating with a central supply pipe (10) installed in each of the different apartment houses and a return connection pipe (40) communicating with a central water return pipe (20)
The central control unit 150 reduces the number of revolutions of the pump unit 140 by the amount of flow reduced by the control of the controller 120 for each household installed in the different apartment houses, And the total flow rate supplied to the apartment house is controlled. [4] The apparatus of claim 1, wherein the central control unit (150)
The optimal flow rate value proportional to the required heat amount of the household is stored in consideration of the heating load for each household, and the optimum flow rate value of the household controlled by the generation-by-household control unit 120 with respect to the sum of the total optimal flow values of the households And the flow rate of the layer-by-layer differential pressure regulating valve (200) is reduced according to the ratio of the flow rate of the bed-side differential pressure-regulating valve (200). [4] The refrigerator according to claim 4, wherein the heating load for each household stored in the central control unit (150)
And calculating the sum of the "heat conduction rate x area × azimuth coefficient x equivalent temperature difference" of each surface constituting one of the rooms in each layer according to the number of rooms.

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