JPH07180074A - Corrosion preventive system of piping equipment of water feeding and distributing system - Google Patents

Abstract

PURPOSE:To improve the cost effectiveness of the corrosion preventive system of piping equipment in a plumbing system by cooling the sealing water of a water sealed vacuum pump sucked and connected to a deaeration module with raw water in a heat exchanger and circulating this water. CONSTITUTION:The raw water from a supply source 1 is supplied to load equipment 4 by a circulating pump 5. The raw water is passed through the deaeration module 11 by a pump 9 through an introducing line 8 branched from its supply path 2, by which the raw water is deaerated. This raw water is fed through a heat exchanger 12 by a feed line 13 to the supply path 2. The deaeration module 11 is connected to the water sealed vacuum pump 15, by which the raw water is sucked and deaerated, thereby the corrosion of the piping equipment is prevented. The water from a water storage tank 16 of the corrosion preventive system described above is passed through the heat exchanger 14 by the circulating pump 17 and is cooled by the raw water. The cooled water is passed as sealing water through the vacuum pump 15 and is then returned to the water storage tank 16.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anticorrosion system for piping equipment in a water supply line for cooling / heating equipment, a water supply / distribution line for structures such as buildings.

[0002]

2. Description of the Related Art As is well known, a deaerator is installed in a water supply line for cooling and heating equipment such as a cooler for the purpose of preventing internal corrosion of these equipment. Further, in recent years, a deaerator has come to be used also as a measure for preventing red water in water supply and distribution pipes in buildings, condominiums and the like. The deaerator used for such an application has a deaerator module connected in the water supply line to the equipment to be used, and the raw water (tap water, well water, other industrial water, etc.) is put in the deaerator module. Water is passed through, and in this water passing process, the inside of the degassing module is evacuated to remove the dissolved gas in the raw water by degassing.

In this type of deaerator, a water-sealed vacuum pump, which has a simple structure and is inexpensive, tends to be frequently used as a means for performing a vacuuming process. For example, put an appropriate amount of sealing water in a casing that has a roughly circular pump chamber, and rotate the impeller slightly eccentric from the center of this casing to cause the sealing water to circulate along the inner wall of the casing by the action of centrifugal force. Due to
A substantially circular space is formed in the central portion of the casing, and the displacement of the space due to the rotation of the impeller causes suction and discharge.

By the way, various corrosion protection systems for piping equipment provided with the deaerator have been proposed. For example, in the anticorrosion system in the closed system pipe for cold water shown in FIG. 3, a deaeration module 34 is inserted in a cold water supply passage 33 between a cold water supply source 31 and a load facility 32, and a suction line is attached to the deaeration module 34. Water-sealed vacuum pump 3 through 35
6 are connected. A sealed water supply passage 37 and a sealed water drainage passage 38 are connected to the water seal vacuum pump 36. Therefore, in the process of the cold water passing through the degassing module 34, the dissolved gas in the cold water is degassed and removed.

However, the corrosion protection system as described above has the following problems. That is, when the temperature of the sealed water of the water-sealed vacuum pump 36 is higher than the temperature of the cold water to be degassed, the degree of vacuum is lowered and the degassing ability is lowered. On the other hand, if the sealed water supplied to the water-sealed vacuum pump 36 is circulated and used, the sealing water temperature rises due to rotation heat and the like, so in order to maintain the required degree of vacuum, it is unavoidable to make it disposable through the drainage channel 38. The reality is that Although this is to maintain the required degree of vacuum, not only is sealing water wasteful and uneconomical, but it is also said that the cost of draining water for sealing water will increase and the installation location will be limited. However, there is a problem as described above, which is a major obstacle to the practical application of this type of deaerator.

[0006]

SUMMARY OF THE INVENTION In view of the above problems, the present invention is intended to realize a corrosion-prevention system having both a circulating use of sealing water and a cooling means for sealing water.

[0007]

The present invention has been made to solve the above-mentioned problems, and it connects a supply source such as raw water and various load equipments through a supply path, and the supply path is provided on the downstream side thereof. The degassing module and the heat exchanger are sequentially inserted toward the air-sealing module, and a water-sealed vacuum pump is connected to the degassing module via a suction line, and between the water-sealed vacuum pump and the heat exchanger. It is characterized in that a circulation circuit for circulating the sealing water of the water-sealed vacuum pump is formed.

[0008]

According to the present invention, the deaerated raw water,
It flows through the heat exchanger into various types of load equipment. The sealed water of the water-sealed vacuum pump circulates with the heat exchanger, and is cooled by the deaerated raw water or the like in the heat exchanger.
As a result, continuous normal operation is performed without degrading the performance of the water-sealed vacuum pump due to an increase in the temperature of the sealed water, and degassed water containing little dissolved gas is stably supplied.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 shows, as an application example of the present invention, a corrosion protection system for piping equipment in cold water closed system piping, and is an explanatory diagram showing the arrangement of each device in this corrosion protection system.

In FIG. 1, the closed system pipe for cold water has, as its basic structure, a cold water supply source 1 and various load equipments 4,
4, are connected by a supply path 2 for supplying cold water to each load equipment 4 and a return path 3 for returning the cold water used in each load equipment 4 to the supply source 1. The cold water supply source 1 includes, for example, a cold water producing device including a refrigerator, a heat exchanger, and a cold water tank. The cold water producing device stores cold water at a predetermined temperature in the cold water tank, and the load of each load facility 4 is increased. Cold water is supplied on demand. The cold water in the supply source 1 is not limited to artificially manufactured by a mechanical device, and natural cold water may be used, for example.

An introductory line 8 which is a main part of the corrosion protection system in this embodiment is connected to an appropriate place of the supply path 2 in a state of being branched from the supply path 2. A chilled water supply pump 9, a filter 10, a deaeration module 11 and a heat exchanger 12 are sequentially inserted in the introduction line 8 toward the downstream side. Outlet end 1 of heat exchanger 12
2a is connected via a feed line 13 so as to communicate with the supply path 2 on the downstream side of the branch point of the introduction line 8. A circulation pump 5 that circulates cold water is provided in the supply path 2 at a position downstream of this connection point. Further, the introduction line 8 and the feeding line 13 are connected via a communication path 2 a equipped with a check valve 6. Further, a flow path switching valve 7 is provided at a connection point between the communication path 2a and the introduction line 8.

The degassing module 11 is provided with, for example, a large number of hollow fiber membranes, and cold water is passed inside the hollow fiber membranes.
The outside is evacuated to remove the dissolved gas in the cold water by degassing in the process of the cold water passing through the hollow fiber membrane. A water-sealed vacuum pump 15 is connected to the degassing module 11 via a suction line 18. This water-sealed vacuum pump 15 is provided with a water-sea inlet 15a for introducing water for pumping on one side, and an extraction suctioned from the degassing module 11 via a suction line 18 on the other side. A drain line 19 for discharging water and sealing water is provided. The drain line 19 is connected to the water storage tank 16 that stores the sealed water.

A coil-shaped member 14 for heat exchange is inserted in the heat exchanger 12, and one end 14a of the coil-shaped member 14 is connected to the sealing water inlet port 15a. The other end 14b is connected to the water storage tank 16 via a water sealing circulation pump 17. Therefore, the sealed water of the water-sealed vacuum pump 15 is circulated through the heat exchanger 12-the water-sealed vacuum pump 15-the water storage tank 16 by the water-sealing circulation pump 17. That is, it constitutes a circulation circuit for cooling the sealed water.

The feed line 13 is provided with a flow path 20 branched from the middle thereof, and the other end is connected to the water storage tank 16. A ball tap 21 for controlling the amount of sealed water stored in the water storage tank 16 is attached to the tip of the flow path 20.

Next, the operation of the anticorrosion system of the pipe structure in the cold water closed system pipe having the above-mentioned structure will be described. First,
As a preparatory work, the sealing water is stored up to a predetermined water level (controlled by a ball tap 21 attached to the tip of the flow path 20 branched from the supply line 13) in the water storage tank 16 for sealing water, and the cold water supply source 1 is also stored. Prepare to supply cold water. Then, in response to a load request from each load facility 4, the water-sealed vacuum pump 1 is based on a command from a controller (not shown).
5, the sealing water circulation pump 17, the supply pump 9 and the circulation pump 5 are driven respectively. Cold water from the supply source 1 flows through the introduction line 8 via the flow path switching valve 7, is purified by the filter 10, and then flows into the deaeration module 11. The cold water that has flowed into the degassing module 11 is the degassing module 1
In the process of passing through the inside of 1, the dissolved gas is removed by the action of the water-sealed vacuum pump 15.

Next, the deaerated and removed cold water flows into the heat exchanger 12 through the introduction line 8, and the water tank 16
The sealed water from is cooled via the coil member 14 for heat exchange. Cold water after heat exchange in the heat exchanger 12 is
By the action of the circulation pump 5, the feed line 13 and the supply path 2
It is supplied to each load equipment 4 via. The cold water after being used in each load facility 4 is supplied to the supply source 1 via the return path 3.
Reflux to.

On the other hand, the sealed water from the water storage tank 16 is cooled in the heat exchanger 12 via the coil-shaped member 14 and flows into the water-sealed vacuum pump 15 as sealed water having substantially the same temperature as the cold water. This prevents the temperature of the sealed water from rising and maintains the sealed water at a constant low temperature. That is, the water storage tank 16-
Due to the circulation circuit that circulates between the heat exchanger 12 and the water-sealed vacuum pump 15, the sealed water is circulated and used while its temperature rise is suppressed. Therefore, the water-sealed vacuum pump 15 into which the sealed water at a low temperature is always introduced evacuates the degassing module 11 to a lower pressure without degrading its performance. The sealed water discharged from the water-sealed vacuum pump 15 flows back into the water storage tank 16 through the drain line 19.

The flow path 20 branched from the supply line 13 supplies the deaerated cold water into the water storage tank 16 by the action of the ball tap 21 attached to the tip of the flow path 20. Therefore, when the sealed water in the water storage tank 16 decreases due to evaporation or the like, the deaerated cold water is stored in the water storage tank 16
It will be supplied to the inside and the degassed water will be used as sealing water. As a result, internal corrosion can be avoided even in the piping equipment or the like that constitutes the circulation circuit for cooling the sealed water.

The connecting passage 2a provided with the check valve 6 is an emergency circuit when the deaeration module 11, the water-sealed vacuum pump 15 and the like are out of order, and when the connecting passage 2a is used,
The flow path of the flow path switching valve 7 is switched from the introduction line 8 side to the communication path 2a side.

Next, as another application example of the present invention, an anticorrosion system for a piping structure in open piping will be described in detail with reference to FIG. FIG. 2 is an explanatory diagram showing the arrangement of each device in this corrosion protection system, like FIG. 1, and the same reference numerals are given to the same member names as in FIG. 1.

In FIG. 2, the open system piping is mainly a piping system of a water supply line for cooling and heating equipment, and its basic configuration is a source 1 of raw water such as tap water and well water and various cooling and heating equipment. , Are connected to each load facility 4 by a supply path 2 for supplying raw water to each load facility 4. A raw water supply pump 9, a filter 10, a degassing module 11 and a heat exchanger 12 are sequentially inserted in the supply path 2 toward the downstream side thereof. A circulation pump 5 that circulates the raw water is provided in the supply path 2 on the downstream side of the outlet end 12a of the heat exchanger 12.

The degassing module 11 and the heat exchanger 12 are constructed in the same manner as in the embodiment shown in FIG. 1, and the water-sealed vacuum pump 15 connected to the degassing module 11 and its sealed water. Since the circulation circuit is also configured similarly to the embodiment of FIG. 1, detailed description thereof will be omitted here. In the embodiment of FIG. 2, the flow path 20 described in FIG. 1 is the outlet end 1 of the heat exchanger 12.
It is configured as a branch from the supply path 2 on the downstream side of 2a.

Next, the operation of the anticorrosion system for the pipe structure in the open pipe having the above-mentioned structure will be described. First,
The preparatory work is the same as the operation described in the embodiment of FIG.

Raw water from the supply source 1 flows through the supply passage 2, is purified by the filter 10, and then flows into the deaeration module 11. Raw water flowing into the degassing module 11 is
In the process of passing through the degassing module 11, the dissolved gas is removed by the action of the water-sealed vacuum pump 15.
Then, the deaerated and removed raw water flows into the heat exchanger 12 through the supply passage 2 and cools the sealed water from the water storage tank 16 through the coil member 14 for heat exchange. Heat exchanger 1
The raw water that has undergone heat exchange in 2 is supplied to each load facility 4 via the supply path 2 by the action of the circulation pump 5.

On the other hand, the sealed water from the water storage tank 16 is cooled in the heat exchanger 12 via the coil-shaped member 14 and flows into the water-sealed vacuum pump 15 as sealed water having substantially the same temperature as the raw water. This prevents the temperature of the sealed water from rising and maintains the sealed water at a constant low temperature. That is, the water storage tank 16-
Due to the circulation circuit that circulates between the heat exchanger 12 and the water-sealed vacuum pump 15, the sealed water is circulated and used while its temperature rise is suppressed. Therefore, the water-sealed vacuum pump 15 in which the sealed water of a low temperature is always introduced evacuates the deaeration module 11 to a lower pressure. The sealed water discharged from the water-sealed vacuum pump 15 flows back into the water storage tank 16 through the drain line 19.

The outlet end 12 of the heat exchanger 12
The flow path 20 branched from the downstream side of “a” supplies the degassed raw water into the water storage tank 16 by the action of the ball tap 21 attached to the tip thereof. Therefore, when the sealed water in the water storage tank 16 decreases due to evaporation or the like, the deaerated raw water is supplied into the water storage tank 16, and the degassed water is used as the sealed water. . As a result, internal corrosion can be avoided even in the piping equipment or the like that constitutes the circulation circuit for cooling the sealed water.

[0027]

As described above, according to the present invention, the sealing water of the water-sealed vacuum pump can be maintained at a low temperature at all times. Continuous operation is possible without
Degassed water with little dissolved gas can be stably supplied. As a result, it is possible to avoid internal corrosion of facility equipment, piping equipment, etc., and extend their life. In addition, since the sealing water can be reused, it is possible to eliminate the waste of the sealing water, the cost of draining the sealing water is completely unnecessary, and the installation location is limited. Can be solved reliably. Furthermore, the corrosion prevention system of the present invention can be unitized and can be inserted into an existing piping system at low cost and very easily, which is very effective as this type of corrosion protection system.

[Brief description of drawings]

FIG. 1 shows an outline of an anticorrosion system for piping equipment in a closed pipe for cold water as an application example of the present invention,
It is explanatory drawing which shows arrangement | positioning of each apparatus in this corrosion prevention system.

FIG. 2 shows an outline of a corrosion protection system for piping equipment in open piping as another application example of the present invention, and is an explanatory diagram showing the arrangement of each device in this corrosion protection system.

FIG. 3 shows an outline of a conventional corrosion protection system for piping equipment in a cold water closed system piping, and is an explanatory diagram showing the arrangement of each device in this corrosion protection system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Supply source 2 ... Supply path 4 ... Load equipment 5 ... Circulation pump 9 ... Supply pump 10 ... Filter 11 ... Deaeration module 12 ... Heat exchanger 12a ... Outlet end 14 ... Coil-like member 14a ... One end Portion 14b ... The other end portion 15 ... Water-sealing vacuum pump 15a ... Water-sealing inlet 16 ... Water tank 17 ... Water-sealing circulation pump 18 ... Suction line 19 ... Drainage line 20 ... Flow path 21 ... Ball tap

Claims (1)

[Claims] 1. A supply source 1 for raw water or the like and various load equipments 4 are connected by a supply path 2, and a degassing module 11 and a heat exchanger 12 are sequentially inserted in the supply path 2 toward the downstream side thereof. Then, a water-sealed vacuum pump 15 is connected to the deaeration module 11 via a suction line 18, and the water-sealed vacuum pump 1
5. A corrosion prevention system for piping equipment in a water supply and distribution system, characterized in that a circulation circuit for circulating the sealing water of the water-sealed vacuum pump 15 is formed between the heat exchanger 12 and the heat exchanger 12.