JPS6213582B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a device for supplying hot water to showers in hotels and hospitals, for example.

(Prior art) Conventionally, water heaters have been configured such that a heater is installed inside a hot water tank, and a hot water supply pipe that connects the hot water outlet and the return port from the hot water tank has a hot water supply equipment. The hot water tank was provided with a water supply port for supplying cold water from the water storage tank to the hot water tank.

(Problem to be solved by the invention) However, as is well known, when you tap hot water from a hot water faucet in a hotel, the hot water becomes milky white due to the formation of extremely small air bubbles. This not only causes discomfort to the drinker, but also causes corrosion of the inner wall of the pipe in which the bubbles are installed.

By the way, to explain the background of the present invention, the inventor of the present application first discovered that corrosion of pipes in heating equipment was caused by dissolved oxygen in hot water, and developed a device for separating the bubbles. The structure of this bubble separator is that an inlet and an outlet are provided on the front and rear side walls of a hollow large-diameter section, an air-extraction chamber is provided protruding from the upper surface of this large-diameter section, and an air-bleeding pipe is inserted into the air-extraction chamber. However, an air action section was provided within this air action chamber (Japanese Patent Application Laid-Open No. 1983-68746). This was to prevent corrosion by forming a coating on the inner wall of the pipe by applying a certain wave motion generated by an impeller pump inside the pipe. In heating equipment, fresh water with a high amount of dissolved oxygen is not replenished very often, so it is extremely efficient to separate dissolved oxygen from the hot water of the heating equipment.

On the other hand, water heaters require a hot water tank, and this tank is connected to a hot water supply pipe, through which hot water is supplied to showers, etc. As water was used, new water had to be replenished frequently into the hot water tank, leading to faster corrosion of the hot water tank. Also, hot water was not always used at night, but only temporarily. Therefore, a thermal shock occurs due to the temperature difference between the hot water and the cold water, and the gas dissolved in the cold water becomes bubbles, and these bubbles corrode the inner wall of the hot water tank. Furthermore, the difference in temperature inside the hot water tank is not limited to when cold water is supplied as mentioned above; when the shower is not in use, such as at night, the hot water in the hot water tank can easily flow upward and downward in about 10 minutes. This creates a temperature difference between the hot water tank and the hot water tank, which accelerates corrosion within the hot water tank. Therefore, an attempt was made to install the above-mentioned bubble separator and impeller pump in the middle of the hot water supply pipe, but the pump had sufficient capacity to supply hot water to the pumps installed throughout hotels and other buildings, and this prevented corrosion. It is uneconomical to drive the motor all the time due to high running costs.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a water heater that can prevent corrosion of the inner wall of a hot water tank at low cost.

(Means for Solving the Problems) A feature of the present invention is that the circulation outlet 14 is provided at the top of the hot water tank 1 separately from the hot water pipe.
A circulation pipe 16 is specially provided to communicate the hot water tank with an inlet 15 provided at the bottom of the hot water tank, and an impeller pump 17 and a bubble separator 18 are provided downstream of this pump in the middle of this pipe. There it is.

(Function) Therefore, the hot water in the hot water tank 1 is constantly circulated from the outlet 14 of this tank to the inlet 15 through the circulation pipe 16 by the operation of the impeller pump 17. There is no temperature difference between the top and bottom of the hot water inside. Therefore, it is also useful for preventing corrosion caused by the action of an oxygen concentration battery. Furthermore, since the circulation pipe 16 is provided with a bubble separator 18 downstream of the impeller pump 17, dissolved oxygen in the hot water in the hot water tank 1 is separated, and furthermore, the pump 17
The waves are passed through the bubble separator 18 to the hot water tank 1.
As the rust propagates inside, an anti-rust coating is formed inside the hot water tank.

(Example) Examples of the present invention will be described below based on the drawings.

In FIG. 1, a hot water tank 1 is connected to support columns 2, 2.
A joint box 4 is supported by a heater 3 that uses electricity, steam, etc. as a heat source.
It is installed by. A hot water pipe 7 is disposed between the hot water outlet 5 and the return port 6, and a pump 8 supplies hot water to a shower 9 and the like. A water supply pipe 12 from a water storage tank 11 communicates with the water supply port 10, and one end opening of a preheating pipe 13 that preheats cold water is connected to this water supply port. The opening is directed toward the heater 3, particularly below the heater, so that the water can be easily heated by the heater. Next, in order to circulate the hot water in the hot water tank 1, an outlet 14 for circulation is provided at the top of the hot water tank, and an inlet 15 is provided at the bottom of the hot water tank, and a connection is made between the outlet and the inlet. An impeller pump 17 and a bubble separator 1 are installed near the outlet midway through the circulation pipe 16.
8 is provided.

The specific structure of the bubble separator 18 is that, as shown in the second diagram, front and rear plates 20 and 21 are joined to both ends of a cylindrical hollow large diameter part 19, and an inlet port is provided at the upper part of the front plate. A mounting pipe 22 is attached. A circulation pipe 16 from the pump 17 is fixedly connected to the mounting flange of the mounting pipe 22. The diameter of the large diameter portion 19 is determined by the amount of water flowing in from the pipe 16, the flow rate, the turbulent flow state, etc., but it is usually most desirable to have a diameter approximately 2 to 5.5 times the diameter of the attachment pipe 22. Further, the axial length of the large diameter portion 19 is most preferably about 2 to 9 times the diameter in terms of water bubble separation effect and manufacturing cost.

Next, an air action chamber 23 is provided projecting from a part of the upper surface of the large diameter portion 19. And cushion room 2
3 is installed so that the axis of this chamber is this large diameter section 1.
9 to 4 of the total length of the large diameter portion is preferably located inward from the tip of the large diameter portion. The upper plate 24 connected to the upper end opening of this air action chamber 23
An air vent pipe 25 extends vertically through the center of the air vent pipe, and the lower end opening of this air vent pipe reaches at least one-half of the air action chamber. Cushion part 2
6. An automatic venting device 27 (FIG. 1) is provided at the upper end of the venting pipe 25.

Below the rear plate 21 is a mounting pipe 2 that forms a discharge port.
8 is provided, and a pipe 16 is connected to this attachment pipe. The hot water passing through the pipe 16 flows into the hot water tank 1 through the circulation inlet 15 provided on the lower surface of the hot water tank 1 and being diffused by the diffusion plate 29 . In addition, 30 is a safety valve, 3
1 is a blow.

To explain the operation of the present invention, when the hot water in the hot water tank 1 decreases due to the use of the shower 9, cold water is supplied from the water storage tank 11 to the hot water tank 1 via the water supply pipe 12. enters the hot water tank through the preheating pipe 13. Therefore, the cold water is heated in the preheating pipe 13 and then supplied to the hot water tank 1.
The temperature difference between the hot water and the existing hot water in the hot water tank 1 is alleviated. Of course, hot water is supplied to the shower 9, etc. by the pump 8.

It is important to constantly circulate the hot water in the hot water tank 1 so that no temperature difference occurs within the hot water tank. Therefore, the hot water that comes out from the outlet 14 provided on the top surface of the hot water tank 1 is returned to the inlet 15 provided on the bottom surface of this tank, and air bubbles are separated by an impeller pump 17 in the middle of this circulation path. The hot water accumulates in the hollow large diameter section 19 of the device 18, so that the air action chamber 23 and the vent pipe 25 are initially filled with warm water. Thereafter, the hot water heated by the heater 3 and separated from the dissolved gas is pumped by the pump 17 and flows into the hollow large diameter portion 19 in a turbulent state. At this time, the vaporized gas generated when the pressure is increased or decreased by the blades of the pump 17 is separated and released into the atmosphere in the following manner. That is, the water flowing into the large diameter portion 19 is decelerated to, for example, one tenth, and at the same time, the turbulent flow caused by the pump 17 is rectified by the cushion portion 26.
It suppresses wave motion and at the same time helps separate bubbles. The separated air bubbles fill the cushion portion 26, and the excess gas moves into the pipe through the opening at the lower end of the air vent pipe 25, and is discharged from the automatic air venting device 27. The hot water discharged from the gas separator 18 enters the hot water tank 1 through the inlet 15 on the lower surface of the hot water tank 1, and exits again through the upper outlet 14 for circulation. Therefore, there is no temperature difference between the top and bottom inside the hot water tank 1.

By propagating the wave motion of the pump 17 into the hot water tank 1 through the bubble separator 18, a rust-preventive coating is formed inside the hot water tank, which has the effect of suppressing corrosion. When the state was observed, it was found that a heavy metal coating was formed inside the hot water tank 1 (the same was true inside the pipes 7 and 16), and this anti-rust action completely prevented the generation of red water. Chemical analysis of this coating revealed that 24.20% silicic acid, 9.92% aluminum oxide or ferric oxide, and calcium oxide.
0.10%, magnesium oxide 0.04%, zinc oxide 43.97
%, copper oxide 6.43%. Incidentally, this copper oxide is used when copper is used for pipes.

In addition, the water in the hot water tank 1 returns to the inlet 15 from the circulation outlet 14 through the pipe 16, but on the way it is stirred by the bubble separator 18, diffused by the diffusion plate 29 provided at the inlet, and returned to the outlet 15. The water in the hot water tank remains at a constant temperature, eliminating temperature differences, which helps prevent corrosion caused by the oxygen concentration battery.

(Effects of the Invention) The present invention having the above configuration prevents the occurrence of thermal shock due to temperature differences, prevents corrosion of the inner walls of hot water tanks and hot water supply and circulation pipes, eliminates the generation of red water, and It is extremely safe for water heating equipment because no chemical agents are used to prevent corrosion, and there is very little air bubbles, so the hot water does not turn milky white. There is no difference in temperature. In addition, since the impeller type pump can be used with a capacity that is limited to the ability to circulate hot water within the circulation pipe, it is also cost effective.

[Brief explanation of the drawing]

FIG. 1 is a schematic sectional view, and FIG. 2 is an enlarged sectional view of main parts. 1...Hot water tank, 3...Heater, 5...Hot water supply outlet, 6...Hot water supply return port, 7...Hot water supply pipe, 11...
Water storage tank, 12...Water supply pipe, 13...Preheating pipe, 16...Circulation pipe, 17...Impeller type pump, 18...Bubble separator, 19...Central large diameter section, 2
3...Air action chamber, 25...Air vent pipe, 26
...Air action section, 27...Automatic venting device.

Claims (1)

[Claims] 1. A heater 3 is installed inside a hot water tank 1, and a hot water supply equipment 9 is installed in the middle of a hot water pipe 7 connecting a hot water supply outlet 5 and a return port 6 from the hot water tank. In the water heater, the hot water tank is provided with a water supply port 10 for supplying cold water from the water storage tank 11 to the hot water tank, and the hot water tank has a circulation outlet 14 provided at the upper part of the hot water tank. Inlet 1 located at the bottom of this hot water tank
An impeller pump 17 and a bubble separator 18 are installed downstream of this pump in the middle of the circulation pipe 16 that communicates with the circulation pipe 16.The structure of the bubble separator 18 is as follows: A hollow large diameter part 19 having an inlet 22 and an outlet 28 at 21, an air action chamber 23 projecting from the upper surface of this hollow large diameter part, and an air action part 2 in the air action chamber.
6. 2. The hot water supply device according to claim 1, characterized in that a diffusion plate 29 is provided in the hot water tank at the circulation inlet.