JPH0246879B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a load device used for measuring and testing the power output characteristics of generators, inverters, etc.
The present invention relates to an open circulation thermal electrode water cooling treatment device that is used to cool thermal waste water of a water resistor that uses water as electrode water.

[Conventional technology] In the past, this kind of hot water was discharged without being cooled or passed through a heat exchanger, so in the former case, it had a negative impact on the natural and living environment and caused pollution problems. There were problems with resource conservation. For example, a water resistor has been conventionally used as a load device for testing the output characteristics of a generator.
A frame d consisting of three electrode plates b connected to high-voltage cables a of each phase is installed and suspended in a water tank c measuring approximately 3 m in length and width and 2 m in height, and the load is adjusted by adjusting the amount inserted into the water. It is used as follows,
The output power of the generator is consumed by using the water in tank c as a resistance. Due to this power consumption, the water temperature gradually rises and the conductivity of the water increases, so if this continues, dielectric breakdown of the water will occur and an arc will occur, which is dangerous. Therefore, in order to prevent this, there is a fifth
As shown by the arrow in the figure, it is essential to constantly supply cold water from a river, fire hydrant, or water storage tank, while draining warm water to maintain the water temperature in the water tank c below a certain level. Therefore, when using the water resistor α, a large amount of water is first required.

To illustrate this concretely, by supplying water at 20℃,
Assuming that hot water at ℃ is discharged (70-20) x 1 = 50
If the generator output is 1000KW, assuming that [kcal/], that is, 50 [kcal] of heat is dissipated per unit,
First, converting the generator output into heat amount is 1000 x 860 =
860,000 [kcalh], divided by the heat dissipated by water per 1 m ³ (50 x 1000 = 50,000 kcal), it turns out that 17.2 [m ³ ] of water is required per hour. If this is used for 8 hours, 17.2×8≒140 [m ³ ] of water will be required.

In addition to being difficult to secure this amount of water, the water resistor α has the drawback that a stable resistance value cannot be obtained because the conductivity of water changes depending on the amount of impurities it contains.

A further serious drawback is that when water resistor α is used, a large amount of heated waste water is generated. This is because under the above conditions in urban areas, i.e. 1000KW.
If we conduct a load test on a generator of 17.2 [m ³ / h] and pour hot wastewater at 70°C into the sewer, hot water will overflow around the area depending on the drainage capacity, and even if it does not overflow, the hot water will introduce bacteria. This is because the sewage purification function deteriorates as the sewage plants die, and sewage management sometimes prohibits load tests.

As a load device used to measure the characteristics of generators, water resistors have the following disadvantages: they pose a risk of arcing, require large amounts of water, have unstable resistance values, and generate large amounts of heated wastewater. This method had various problems such as the occurrence of.

[Problems to be Solved by the Invention] However, the present invention provides an open circulation system in a suitable water resistor that is effective in enabling recycling without generating hot electrode waste water and significantly reducing the consumption of cooling water. It is an object of the present invention to provide a thermal electrode water cooling treatment device.

[Means for Solving the Problems] The open circulation heating electrode water cooling treatment device in the water resistor of the present invention faces the radiator through which hot water is introduced and passes through the interior, and sprays water onto the radiator. , a spray pipe that cools the heated waste water inside the radiator using the latent heat of vaporization of the sprayed water, a filter that is placed immediately in front of the radiator and that aims to lower the conductivity of the electrode water that is supplied to the radiator; A water container, a fan and a louver are respectively installed to cool the surface of the radiator and to diffuse the steam generated from the radiator into the space.

[Example] An example of the present invention to which an electrode water cooling treatment device is applied will be described based on FIGS. 1 to 4.

Before explaining the electrode water cooling processing device A, a brief explanation will be given. B in FIGS. 1 to 4 is a water resistor created by the present inventor and which is currently under separate application.

This water resistor B has a bottomed cylindrical base electrode 3 which has a water supply hole 1 in the middle part of the wall side and a drainage hole 2 in the bottom part to store a predetermined amount of water inside, and the bottom part of the base electrode 3. A cylindrical main electrode 6 is erected through an insulator 1 fixed at the center, and a cylindrical main electrode 6 is connected to the output cable 5 of the generator at its lower end. It consists of an insulating sheath tube 7 that covers the main electrode 6.

Although there is only one water resistor B in FIGS. 1 to 4, there are three water resistors in a set, and the main electrode 6 connects each of the three phases of the generator, while the base electrode 3 Connect them together and ground them. Therefore, it becomes a Y-connected resistor.

The electrode water cooling treatment device A, which is an open circulation heating electrode water cooling treatment device in the water resistor of the present invention, cools the water discharged from the water resistor B and sends it again. A spray pipe 9 that sprays water, a fan 10 that blows air from behind the spray pipe 9, and the fan 1
A louver 11 that guides the air sent to the front of the radiator 8 at 0 and scatters it into the upper space, and a recovery water tank 12 that is disposed below the radiator 8 and collects water that is sprayed onto the radiator 8 from the spray pipe 9 and falls. The following pipe line is formed between the water resistor B and a water storage tank 13 in which water circulating between the radiator 8 and the water tank 13 is stored in advance.

That is, the water stored in the water storage tank 13 is pumped through the pure water pump 15 from the suction pipe 14 vertically installed in the water.
pumping filters 16 and 17, and a water purifier 1 for increasing purity, such as an ion exchange resin water purifier 1.
8, the filled water is sent to the water resistor B from the lower discharge port 8a of the radiator 8 through the pure water filling pipe 19 and the pure water filling pipe 19, which supplies the water to the radiator 8. A cooling circulation pipe 21 that sends the hot water discharged from the container B to the upper inlet 8b of the radiator 8 with the interposed pump 20, and a pure water pump 15 that carries the water sent out from the lower outlet 8a of the radiator 8. A flushing return pipe 23 returns the pure water to the pure water filling pipe 19 while being cooled through a cooling coil 22, and a suction pipe 14 vertically installed in the water storage tank 13 and the collection water tank 12 are connected to a spray pump 24. A spray water supply line 26 for drawing up water from either one of the suction pipes 25 vertically installed and sending it to the spray pipe 9 is formed via switchable switching valves 27, 28, and 29. In FIG. 1, 30 is a fan motor, 31, 32, and 33 are speed controllers for the fan motor 30, the pure water pump 15, and the spray pump 24, respectively, and 34 is a cooling coil.

[Function] Electrode water cooling treatment device A configured as above
We will discuss the effects of

First, as shown by arrows in FIG. 2, purified water is supplied to the radiator 8 through the suction pipe 14 and the pure water filling line 19, and is filled into the water resistor B. That is, water sucked up by the pure water pump 15 from the water storage tank 13 passes through the pure water pump 15, passes through the cooling coil 34, removes sand etc. with the filter 16, enters the filter 17, removes chlorine, and becomes pure water. vessel 18
to go into. The conductivity at this time is about 200 for ordinary tap water.
[μs/cm], but this is approximately 1
It is lowered to [μs/cm]. When this water is supplied to the radiator 8, since the electrode water pump 20 is not operated at this point, the water is filled into the water resistor B through the cooling circulation pipe 21 from both directions as shown by the arrows.

This completes the water filling operation, but if as a result of turning the electrode water pump 20, impurities are dissolved and the conductivity becomes high, drain the water once and repeat the operation from the beginning.

Here, since the maximum operating temperature of the water purifier 18 is 40° C., the cooling coils 22 and 34 are used to cool the water to a temperature below this temperature.

Next, after closing the pure water filling pipe 19 with the switching valves 28 and 29, the electrode water pump 20 is operated to pump the filled water into the cooling circulation pipe 19 as shown by the arrow in FIG.
Circulate the inside of 1.

At the same time, the spray pump 24 is also activated, and the suction pipe 14 is connected to the water storage tank 13 as shown by the arrow in FIG.
The water is sucked up, passed through the spray water supply pipe 26, and sprayed from the spray pipe 9 toward the radiator 8 as shown by the dotted line. On the other hand, the fan motor 30 is also operated to turn the fan 10 and blow air from the back side of the radiator 8.

Therefore, while passing through the water resistor B, the water consumes electric power as a resistance, becomes hot water, and is sent to the radiator 8, but this hot water is cooled by the sprayed water and wind while passing through the radiator 8. . On the other hand, the sprayed water absorbs the heat of the hot water passing through the radiator 8 on the surface of the radiator 8, evaporates, and is sent out by the air blown from the back of the radiator 8, which is then sent to the guide plate of the louver 11 arranged in front of the radiator 8. It blows up and diffuses above the electrode water cooling treatment device A along line 11a as shown by the dotted arrow. Thereafter, the water cooled by the radiator 8 is supplied to the water resistor B again.

Water that is not completely evaporated by the water sprayed during cooling of the radiator 8 adheres to the louver 11 and falls under its own weight, so that it is collected in the collection tank 12. Therefore, when the water level in the collection water tank 12 is nearly full, the switching valve 27 is switched to allow the water in the collection water tank 12 to be sucked up by the spray pump 24 through the suction pipe 25 and sent to the spray pipe 9.

Alternatively, the collection water tank 12 and the water storage tank 13 may be communicated with each other, and the suction pipe 25 and the switching valve 27 may be omitted.

If you wish to lower the electrical conductivity of the circulating water during operation, switch the switching valves 28 and 29 to circulate the water through the flushing return pipe 23 and the pure water filling pipe 19 as shown by the arrows in Fig. 4. Let them do it. That is,
Water is discharged from the radiator 8, passes through the cooling coil 22, is sent to the cooling coil 34 by the pure water pump 15, and then returns to the radiator 8 through the filters 16, 17 and the water purifier 18, so that foreign substances and chlorine are removed. can lower the conductivity.

[Effects] As described above, the electrode water cooling treatment device of the present invention cools and circulates the hot water discharged from the water resistor, so there is no need to release hot water to the outside, and the hot water is cooled by evaporation. Therefore, it has a heat dissipation capacity equivalent to the latent heat of vaporization of water (560 kcal/). This is approximately 11 times the capacity of the hot water discharge method described above (560/50≒11), so the required amount of water is only about 1/10, even considering the loss of water scattering. Furthermore, a flushing return pipe 23 is arranged, and the flushing return pipe 23 and the filters 16 and 17 are connected to each other.
A deionizer 18 is interposed to allow free circulation between the deionized water filling pipe 19 and the radiator 8 at any time, so the conductivity of the water can be adjusted and the resistance value can be kept constant. Not only collection tank 12
By providing this, extremely excellent effects such as minimizing water scattering loss can be achieved.

[Brief explanation of the drawing]

1 to 4 each show an embodiment of the present invention, and are explanatory diagrams of a water resistor B and an electrode water cooling processing device A used in connection with the water resistor B, and FIG. 5 shows a conventional water resistor. FIG. A... Electrode water cooling treatment device, B... Water resistor,
α... Water resistor, a... High voltage cable, b... Electrode plate, c... Water tank, 1... Water supply hole, 2... Drain hole, 3... Base electrode, 4... Insulator, 5... Output cable, 6... Main electrode, 7... Insulating sheath tube, 8...
...Radiator, 8a...Discharge hole, 8b...Injection hole, 9...Spray pipe, 10...Fan, 11...
...Gallery, 12...Recovery water tank, 13...Storage tank, 14...Suction pipe, 15...Pure water pump, 1
6, 17...Filter, 18...Water purifier, 19
...Pure water filling pipe line, 20...Pump, 21...Cooling circulation pipe line, 22...Cooling coil, 23...Flushing return pipe line, 24...Spray pump, 2
5...Suction pipe, 26...Spray water pipe, 2
7, 28, 29...Switching valve, 30...Fan motor, 31, 32, 33...Speed controller, 34...
...cooling coil.

Claims (1)

[Scope of Claims] 1. A radiator for introducing hot water discharged from the water resistor into the water resistor and cooling it at a constant temperature by passing it through the water resistor in the middle of the circulation path of water used as a resistor in the water resistor; A filter and a water purifier provided in a water circulation path connected in parallel with the water circulation path and the entire opposite side of the radiator are sprayed with water, and the radiator is heated by the latent heat of vaporization of the sprayed water. A spray pipe that cools and maintains the temperature of the hot water inside the radiator, and a fan that is disposed behind the spray pipe and cools the surface of the radiator to keep the hot water inside the radiator at a constant temperature and blows off water adhering to the surface and steam generated therefrom. The radiator is placed on the side opposite to the side where the spray pipe and the fan are installed, and receives water droplets and steam blown away by the fan, separates steam and water, and dissipates the steam. An open circulating heating electrode water in a water resistor that is equipped with a louver that promotes water recovery and that constantly controls the temperature and purity of the water used as a resistor in the water resistor to maintain and manage a constant conductivity. Cooling treatment equipment. 2. An open circulating thermal electrode water cooling treatment device in a water resistor according to claim 1, wherein the louver is provided with a collection tank below which collects water that has not completely evaporated and falls due to its own weight. . 3. The open circulation thermal electrode water cooling treatment device in a water resistor according to claim 2, wherein the recovery water tank is in communication with a storage tank that stores water sprayed from a spray pipe.