JP2000303514A - Pressurized feedwater system for intermediate or high- rise building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pressurized feedwater system for an intermediate or high-rise building capable of always effectively utilizing the feedwater pressure in the city water pipes with a simple structure and capable of sufficiently reducing the cost. SOLUTION: Water is supplied to the faucets 10a to 10c in the lower floors through a feedwater pipe 3 directly from a city water distributing pipe 1, and the feedwater for the faucets 10d to 10f in the higher floors is pressurized by a booster pump 4 whose suction pipe is connected to the feedwater pipe 3 and is fed through a feedwater pipe 8. Since the city water in the lower zone is fed only by the hydraulic pressure in the city water pipe, depressurization can be dispensed with, and the booster pump 4 is operated only to obtain the pressurization necessary for the higher zone, so that the hydraulic pressure in the city water pipe is sufficiently utilized. As a result, depressurization in the lower zone is unnecessary, so that necessary energy can be reduced, and the water supply to the lower zone can be constantly maintained even without a bypass line.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply system for a middle-to-high-rise building which is directly connected to a water supply pipe for water supply, and more particularly to a case where the water pressure of the water supply pipe can be expected to be a predetermined value or more. It relates to a booster water supply system.

[0002]

2. Description of the Related Art In Japan, the water pressure of water pipes (water pipes for water supply) is generally guaranteed to be a predetermined value by a water utility such as a local government. In terms of height, for example, 20m or more (3 stories: actual head 2.6m × 3,
Loss due to pipeline resistance is 20% of actual head, required end pressure 1
0m). Therefore, even if water is supplied from any of the water utilities, if the floor of the building to be supplied becomes higher than a certain level, it is impossible to supply water to the upper floor only by the water pressure of the water pipe. A water supply system using a pump has been conventionally used in the building.

In a water supply system using such a pump, the use of a water receiving tank is conventionally required from the viewpoint of a buffer function for water pipes and sanitary aspects. In the existing water supply system, despite the fact that water pressure was given to the water pipe, it could not be used effectively, and there was a problem from the viewpoint of energy saving (energy saving).

However, in recent years, it has been found that there is no particular problem even in such a case without the use of a water receiving tank in accordance with the improvement of the functions of the facilities. The water supply system, in which a pump is directly connected to a pipe and used as a booster pump (booster pump), has been attracting immediate attention because the water pressure of the water pipe can be used effectively and energy can be saved. .

Therefore, a conventional example of such a water supply system directly connected to a water pipe will be described. This system is roughly classified into two types as shown in FIGS.
The proper use of these depends on the water pressure of the water pipe to which the system is connected. By the way, the value of this water pressure is
Depending on the water utility, as mentioned above,
It is in the range of 1.0 to 3.5 Kgf / cm ² , and also varies depending on the undulation and length of the water pipe due to the difference in topography.

[0006] However, the above-mentioned proper use mainly depends not on the value of the water pressure itself but on its fluctuation. That is, when it is assumed that the water pressure fluctuation is relatively large,
The method of FIG. 6 is mainly adopted, and the water pressure is relatively stable.
Moreover, when the value is 20 m or more in height conversion, FIG.
Is selected.

First, the water supply system shown in FIG. 6 will be described. In this system, tap water having a predetermined pressure taken in from a water supply pipe 1 via a water meter 2 and a water supply pipe 3 is directly supplied to a booster pump 4. Of the suction pipe. Then, the tap water whose pressure has been increased by the pressure intensifying pump 4 is supplied from the discharge pipe to a water supply pipe 8 via a check valve (check valve) 5, and further supplied to the water on each floor of the building to be supplied with water. The plugs (load faucets) 10a to 10f are supplied.

[0008] At this time, the pressure increase by the pump 4 is set to a water pressure at which a predetermined amount of water can be ensured even for the faucet on the top floor.
Water is supplied through the pressure reducing valves 9a to 9d.
Further, in this system, the pump 4 is provided with a bypass water supply pipe 7 having a check valve 6, so that even when the pump 4 cannot be operated due to a power failure or the like, a certain level of water supply capacity can be secured. It has become.

Next, in the system shown in FIG. 7, the floor of the building to be supplied with water is divided into a high-rise zone and a low-rise zone.
Separately, a water supply pipe 11 connected to the water supply pipe 1 via the water meter 2 is provided. For the floor of the low-rise zone (the floors from the first floor to the third floor in this example), only the pressure of the water pipe is provided. Therefore, as shown in the figure, the pressure reducing valve 9d is provided only in the pipe of the faucet 14d on the fourth floor, which is the lowest floor, of the floors belonging to the high-rise zone, as shown in the figure. is there.

In these systems, an inverter is generally used to drive the pump 4 and a variable speed operation water supply system is used. As a result, the pump 4 according to the amount of water supply is used.
Energy savings can be obtained by the variable speed operation described above, and the water pressure of the water pipe can be effectively used, and further sufficient energy savings can be obtained. Further, in the system of FIG. 7, the floor of the low-rise zone is supplied with water only by the pressure of the water pipe, so that more effective use of energy can be obtained.

[0011]

However, the prior art described above does not sufficiently consider the simplification of the configuration.
There was a problem in terms of cost reduction.

That is, first, the system shown in FIG. 6 requires a number of pressure reducing valves and a bypass water supply pipe.
It is difficult to reduce costs. In general, for example, in the case of a booster water supply system intended for a middle-to-high-rise building exceeding three floors, the water supply pressure is at most 30 if it is about 5 to 6 floors.
m, so a pressure reducing valve is not required, but in buildings with more floors than this, the discharge pressure of the booster pump becomes considerably higher,
As a result, a pressure reducing valve is required on some floors of the high-rise zone, including the low-rise zone. Generally, a pressure reducing valve is required each time the feedwater pressure exceeds approximately 3.0 kgf / cm ² .
As a result, in the conventional example of FIG.
Although the water pressure of the water pipe is used effectively, the low-rise zone requires a particularly large number of pressure reducing valves and, as mentioned above, a bypass water supply pipe equipped with a check valve. It becomes complicated and cost reduction becomes difficult.

Next, in the system shown in FIG. 7, a separate water pipe for the low-rise zone is required. As a result, the configuration becomes complicated and the cost reduction becomes difficult.

It is an object of the present invention to provide a booster water supply system for middle and high-rise buildings, which has a simple structure, can always effectively use the water supply pressure, and can sufficiently reduce the cost.

[0015]

The object of the present invention is to divide each floor of a medium-to-high-rise building to be supplied with water into a high-rise zone and a low-rise zone, and to provide a low-rise zone with a floor directly connected to a water pipe. Water is supplied by the floor-side water supply pipe, and on the floor of the high-rise zone, a booster pump in which a suction pipe is connected to the low-floor floor-side water supply pipe is used. It is designed to be supplied with water.

[0016]

[Function] Since the low-rise zone is supplied only with the water pressure of the water pipe, there is no need to reduce the pressure. The booster pump only needs to work to obtain the required pressure increase in the high-rise zone. As a result, combined with the fact that decompression in the low-rise zone becomes unnecessary, the required energy can be reduced, and water supply to the low-rise zone can be performed without a bypass pipe. The possibility of interruption can be eliminated.

[0017]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a booster water supply system for a high-rise building according to the present invention.
Fig. 1 shows a 6-story building as a building for water supply. The first to third floors are divided into low-rise zones (low-floor groups), and the fourth to sixth floors are divided into high-rise zones (high-floor groups). One embodiment in which the present invention is applied, which corresponds to the invention described in claim 1. In the drawings, 12 and 14 are pressure sensors, 13 is a flow switch, and 15 is a pressure tank. (Accumulator) and 16 is a control device, and other components are the same as those of the prior art described with reference to FIGS.

In the description of this embodiment, the water supply pipes 3 and 8 will be described separately for the low-rise zone water supply pipe 3 and the high-rise zone water supply pipe 8. First, in this embodiment, the suction pipe of the booster pump 4 is a part of the water supply pipe 3 for the low-rise zone, and a position where a water pressure of about 0.2 to 0.5 kgf / cm ² can be secured, for example, the water supply pipe 3 The discharge pipe is connected to a part of the rising pipe, and the high-rise zone water supply pipe 8
It is connected to the. In this embodiment, the pressure of the tap water supplied from the water supply pipe 1 is expected to be approximately 20 m or more. As a result, the low-rise zone water supply pipe 3 is provided.
The water taps 10a to 10c on each floor from the first floor to the third floor connected to the
Water supply is available.

The water pressure sensor 12 functions to detect the pressure on the suction pipe side of the intensifier pump 4, that is, the water pressure at the upper end of the water supply pipe 3 for the low-rise zone, and to input the detected pressure to the control device 16. The flow switch 13 monitors the amount of water supplied from the intensifier pump 4 to the water supply pipe 8 for the high-rise zone, and when the amount of water falls below a predetermined flow rate, generates a predetermined output and inputs it to the control device 16. do.

The water pressure sensor 14 has the function of detecting the pressure on the discharge side of the intensifier pump 4, that is, the water pressure at the lower end of the water supply pipe 8 for the high rise zone, and inputting it to the control device 16. The pressure tank 15 is formed of a so-called accumulator having an air chamber. When water is not used in the high-rise zone, the water pressure in the water supply pipe 8 is maintained at a predetermined value POFF (pump stop pressure). Work on.

As shown in FIG. 3, the control device 16 includes an inverter 16A and a control circuit 16B as main components.
And a commercial three-phase AC power source P
The three-phase AC power R, S, T is received from W, and the three-phase AC power U, V, W having a variable voltage and variable frequency is generated therefrom to operate the booster pump driving induction motor IM at a variable speed. ing.

On the other hand, the control circuit 16B comprises a CPU, a memory M, and input / output interfaces PIO-1 and PIO.
-2, a computer unit comprising PIO-3, and peripheral devices comprising a stabilized power supply AVR, a digital / analog converter D / A, an analog / digital converter A / D, a digital switch SW, etc. The signals from the sensors 12, 14 and the flow rate switch 13 are fetched, and these signals are subjected to a predetermined calculation according to a predetermined program stored in the memory M,
The control signals O and L are supplied to the inverter 16A to control the inverter 16A.

In FIG. 3, SS is a switch for operating and stopping the entire system, STX is a relay and a contact, EBL is an earth leakage breaker, and CONS is an operation panel of the inverter 16A. Therefore, when the switch SS is turned on, power is supplied to the stabilized power supply AVR, the control circuit 16B is activated, the contacts of the relay STX are closed, and the power of the inverter 16A is turned on. It will be operable.

Next, the control operation of the booster pump 4 according to this embodiment will be described. First, as described above, faucets 10a to 10a on each floor from the first floor to the third floor of the low-rise zone.
Since water is supplied to c by the water pressure of the water supply pipe 1, the operation of the booster pump 4 has nothing to do with the water supply operation at this time.

On the other hand, for the faucets 1d to 1f of each floor from the fourth floor to the sixth floor in the high-rise zone, the water pressure of the water distribution pipe 1 alone is not enough. It is supposed to. First, 4 in the high-rise zone
When all of the faucets 1d to 1f on each floor from the first floor to the sixth floor are closed, the water pressure of the high-rise zone water supply pipe 8 is maintained at the pump stop pressure P _OFF by the pressure tank 15 as described above. Therefore, the pump 4 is stopped.

Next, when water is used on the floor of the high-rise zone, the water pressure of the high-rise zone water supply pipe 8 becomes the pump stop pressure P
_{When the} pressure decreases from _OFF and further decreases to the starting pressure P _ON shown in FIG. 2, this is detected by the pressure sensor 14, and
As a result, the control device 16 starts the operation of the pump 4 as shown in FIG. 2, takes in water from the water supply pipe 3 for the low-rise zone, and supplies the increased-pressure water to the water supply pipe 8 for the high-rise zone. To do.

For this reason, first, the pump stop pressure P _OFF , the pump start pressure P _ON , the respective rotational speeds N ₁ , N ₂ , and the like are previously stored in the memory M of the computer in the control circuit 16B by, for example, a digital switch SW. The QH characteristics A, B, and C of the pump at N ₃ , the load load curve F, and other necessary control constants are also stored outside the above-mentioned program. Then, a predetermined control signal is calculated based on signals taken from the pressure sensors 12 and 14, the flow rate switch 13, and the like, and the calculated control signal is supplied to an inverter 16A to operate the pump 4 at a variable speed, thereby obtaining a load load curve shown in FIG. Operation along F is obtained.

That is, assuming that the amount of used water Q in the high-rise zone increases from 0 and the amount of used water Q further increases after the pump 4 starts, control is performed in accordance with the increase in the amount of used water Q. The circuit 16B increases the output frequency of the inverter 16A and increases the rotation speed N of the pump 4. And use it to water Q ₂ in the rotation speed N _2, in such a manner that the amount of water used Q ₃ rotation speed N ₃ In the opposite, if the amount of water used Q it is, began to decrease and Q ₂ → Q ₁ → 0, pump 4
Is reduced to N ₁ → N ₂ → N _3, and when the used water amount Q decreases to a predetermined flow rate QS (0 <QS <Q2), this is detected by a signal of the flow rate switch 13, The rotational speed N of the pump 4 is increased to a predetermined value N ', water is supplied to the pressure tank 15, and the pump 4 is stopped when the water pressure of the high-rise zone water supply pipe 8 reaches the pump stop pressure P _OFF. .

Therefore, according to this embodiment, it is possible to supply water with different water pressures for each hierarchical zone, so that it is not necessary to use a pressure reducing valve, and therefore, there is no energy loss due to pressure reduction. Energy can be saved sufficiently. In addition, since the pump 4 only needs to increase the pressure of a portion that is insufficient with the pressure of the tap water supplied from the water supply pipe 1, the water pressure of the water supply pipe is effectively used.
Energy saving will be obtained.

On the other hand, in this embodiment, since there is no need to provide a pressure reducing valve or a bypass pipe, the cost can be reduced. Further, since the water supply to the high-rise zone is performed by sharing the water supply pipe of the low-rise zone, there is no need to separately provide a water supply pipe dedicated to the low-rise zone. Therefore, the configuration is simplified in this aspect, and the cost is further reduced. be able to.

Next, another embodiment of the present invention will be described. Fig. 4 shows a 9-story building where water is to be supplied.
This is divided into low-rise zones (low-floor group) from the first floor to the third floor,
It is an embodiment in which the present invention is applied to a middle zone (floor group) from the first floor to the sixth floor and a high zone (high floor group) from the seventh floor to the ninth floor. Second
As is apparent from the drawing, this embodiment is different from the embodiment of FIG. 1 in that the booster pump 40 and the check valve 50, each floor from the seventh floor to the ninth floor are added. Water supply pipe 80 for high-rise zone connected to floor faucets 10g, 10h, 10i, pressure sensors 120, 140, flow sensor 1
30, a pressure tank 150 and a control device 160 are added thereto. Therefore, the other parts are the same as those in the embodiment of FIG. 1, but in this embodiment, the floors from the fourth floor to the sixth floor will be described below. The middle-rise zone is described, and the floors from the seventh floor to the ninth floor are described as the high-rise zone. The low-rise zones from the first floor to the third floor are the same as in the embodiment of FIG.

The suction pipe of the pressure intensifier pump 40 is a part of the water supply pipe 8 for the middle zone, and the suction pipe of the first stage pressure intensifier pump 4 is used as a suction pipe.
It is connected to a position where a water pressure of about ² to 0.5 kgf / cm ² can be secured, for example, a part of a rising pipe of the water supply pipe 8, and its discharge pipe is connected to the high-rise zone water supply pipe 80. And, as described above, the water tap 10g for each floor from the seventh floor to the ninth floor is provided in the high-rise zone water supply pipe 80,
10h and 10i are connected.

Therefore, in this embodiment, the water pressure of the water distribution pipe 1 is increased to two levels by the first-stage pressure-intensifying pump 4 and the second-stage pressure-intensifying pump 40, and each floor of the high-rise zone is Water is supplied to the faucets 10g, 10h, and 10i on the floor. For this reason, the control device 160 controls the pressure sensor 12 in the same manner as the first-stage control device 16.
0, 140 and the signal of the flow rate switch 130, the booster pump 140 is controlled at a variable speed, and the operation of the pump 40 is controlled so that the water boosted to a predetermined water pressure is supplied to the faucets 10g, 10h, and 10i. It is supposed to.

However, at this time, in order to supply water by the second-stage pressure-intensifying pump 40, the first-stage pressure-increasing pump 4
Must also be operated at the same time, and therefore, in this embodiment, the pressure sensor 120
The second stage pressure intensifier pump 40 is operated, and when water supply to the high-rise zone is started, the pressure on the suction pipe side of the pressure intensifier pump 40 is increased. The first-stage pressure-intensifying pump 4 is always configured to be in the operating state so as not to decrease from the predetermined value. Specifically, the operation of the first-stage pressure-intensifying pump 4 is controlled so that the pressure on the suction side of the second-stage pressure-increasing pump 40 is always kept at, for example, 1.0 kgf / cm ² . is there.

The pressure required for the second stage pressure booster pump 40
(Total head) is the actual head; 2.6m × 5th floor, pipeline loss; 20% of the actual head, required terminal pressure 10m, water supply pressure by the first stage 10m, etc. 2
3 m, and installed so as to satisfy this condition.

With this arrangement, the pressure on the discharge side of the second-stage pressure-intensifying pump 40 becomes 30 m or less at the maximum, so that it is not necessary to provide a pressure reducing valve on each floor. However, the discharge flow rate of the first stage pressure booster pump 4 needs to be set so as to cover the discharge amount of the second stage pressure booster pump 40.

Next, the operation of the embodiment shown in FIG.
explain. <When water is used on floors from the fourth floor to the sixth floor> When the faucets 10d to 10f are opened, the pressure detected by the water pressure sensor 14 becomes, for example, a set value of 1.0 kgf / cm ² or less. As a result, the first-stage pressure-intensifying pump 4 is started.
After the start, the pressure at the end of the middle zone water supply pipe 8 is 1.0.
The rotational speed of the pressure-intensifying pump 4 is controlled so as to keep the set value of Kgf / cm ² . Then, when the use of water is stopped flow falls below the predetermined value Q _S, the signal of the flow rate switch 13, although the stopping of the pump, this time, once, increasing the rotation speed of the booster pump 4, Water pressure is 1.5kgf
/ Cm ² and accumulates pressure in the pressure tank 15. This control is the same as in the embodiment of FIG.

<When Water is Used on the 7th Floor to 9th Floor> When the faucets 10g to 10i are opened, the pressure of the water supply pipe 80 for the high rise zone decreases. Therefore, when the pressure detected by the pressure sensor 140 becomes equal to or lower than the starting pressure P _{ON of} the second-stage pressure-intensifying pump 40, the second-stage pressure-increasing pump 4
Start 0. And after starting, according to the amount of water supply,
The intensifier pump 40 is operated at a variable speed so that an operation along a predetermined load load curve can be obtained. The control at this time is the same as the control of the booster pump 4 in the embodiment of FIG.

At this time, the pressure detected by the pressure sensor 120 is also monitored at the same time.
The pressure on the suction side of the intensifier pump 40 is equal to the set value (1.0 kgf / cm).
² ) As described above, the operation of the first-stage pressure-intensifying pump 4 is started as described above, and the water is supplied by the series operation of the two pressure-intensifying pumps, the pressure-intensifying pump 4 and the pressure-intensifying pump 40. I do.

At this time, the first-stage pressure-intensifying pump 4 performs a constant pressure control with the target value set at the set pressure (1.0 kgf / cm ² ). Control is performed according to the load load curve. And also at this time, when stopping the pump,
Increase the rotation speed of booster pumps 4 and 40 and increase the water pressure to 1.5 kg
The pressure is raised to f / cm ² and stored in the pressure tanks 15 and 150.

Therefore, also in this embodiment, it is possible to supply water with different water pressures for each hierarchical zone, so that it is not necessary to use a pressure reducing valve. Therefore, there is no energy loss due to the pressure reduction, so that the water pressure can be sufficiently reduced. Energy saving can be obtained. Next, since the pump 4 only needs to increase the pressure of a portion that is insufficient with the pressure of the tap water supplied from the water distribution pipe 1, energy can be saved because the water pressure of the water distribution pipe is effectively used. Will be.

Also in this embodiment, since there is no need to provide a pressure reducing valve or a bypass pipe, the cost can be reduced. Further, since the water supply to the high-rise zone is performed by sharing the water supply pipe of the low-rise zone, there is no need to separately provide a water supply pipe dedicated to the low-rise zone. Therefore, the configuration is simplified in this aspect, and the cost is further reduced. be able to.

By the way, in the embodiment of FIG. 4, almost every time the second-stage pressure-intensifying pump 40 starts operating, the first-stage pressure-increasing pump 4 is also started. There is a concern that the frequency of starting the pressure booster pump 4 at the stage becomes considerably high. Therefore, if the increase in the starting frequency is not preferable, the capacities of the pressure tanks 15 and 150 may be increased as needed.

In the embodiment shown in FIG. 4, the case where two pressure intensifier pumps are used has been described. However, the present invention is applicable to a greater number of, for example, n (n> 3, 4,...) It is needless to say that the use of the booster pump enables application as a water supply system in a building of any floor from a high rise to a super high rise.

[0045]

According to the present invention, the following effects can be obtained.

(1) Since there is no need for a water supply pipe for bypass or a dedicated water supply pipe for the third floor or lower, the construction cost required for piping equipment can be reduced.

(2) Since a pressure reducing valve is not required for water supply in the low-rise zone, equipment costs can be reduced.

3. Since pressure tanks are installed in each stage from the first stage to the nth stage, and pressure control can be performed here, even when the operation of the pump is stopped due to a power failure or the like, Thus, the occurrence of the water hammer phenomenon can be prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of a boosted water supply system for a middle- and high-rise building according to the present invention.

FIG. 2 is an operation characteristic diagram of a pump in one embodiment of the present invention.

FIG. 3 is a circuit diagram showing a control device according to one embodiment of the present invention.

FIG. 4 is a block diagram showing another embodiment of the present invention.

FIG. 5 is a circuit diagram showing a control device according to another embodiment of the present invention.

FIG. 6 is a block diagram showing a first conventional example of a water supply system.

FIG. 7 is a block diagram showing a second conventional example of a water supply system.

[Explanation of symbols]

 1 Water supply pipe 2 Water meter 3 Water supply pipe (water supply pipe for low-rise zone) 4, 40 Booster pump (booster) 5, 50 Check valve (check valve) 8, 80 Water supply pipe (water supply pipe for high-rise zone) 10a to 10i Water taps on each floor 12, 14, 120, 140 Pressure sensor 13, 130 Flow switch 15, 150 Pressure tank 16 Controller

Claims (2)

[Claims] 1. Each floor of a middle-high-rise building is sequentially
It is divided into at least three floor groups, and water supply to the floors belonging to the lower floor group is performed by the lower floor group water supply pipe directly connected to the water supply pipe, and to the floor groups other than the lower floor group. Water supply to the floor to which it belongs is performed in each of the floor groups by a water supply system for each high floor group connected to the discharge side of the dedicated pressure booster pump. The suction side is sequentially connected to a water supply pipe on the lower floor group side of the floor group, respectively, so as to supply water. A booster water supply system for middle- and high-rise buildings, characterized in that when operation is started, the booster pumps in the floor groups immediately below the floors also start rotating at the same time. 2. The invention according to claim 1, wherein when the booster pump on the upper floor group starts operating, the pressure on the suction side of the booster pump is at least 1.0 kgf / c.
As it kept in m ^2, pressure feed water system up for High-rise buildings, characterized by being configured such that the immediately lower floor group intensifier pumps are subjected to operation control.