JPS63190308A - Water resistor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a load device used for measuring and testing the output characteristics of a power supply device such as a generator.

[Prior Art] A water resistor is used as a conventional load device of this type. As shown in Figure 5, this water resistor (α) has three electrode plates (b) connected to three-phase high voltage cables (a).
), the frame (
d) is installed and suspended, and the load is adjusted by adjusting the amount inserted into the water.Water 4! (C)
It uses the water inside as a resistance and consumes the output power of the generator. 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, to prevent this, the water tank (C) is always connected to the river, as shown by the arrow in Figure 5.
While supplying cold water from a fire hydrant or water tank, it is essential to drain warm water and 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 show this concretely, assuming that water at 20°C is supplied and hot water at 70°C is discharged (70-20)X1=50[kc
al/n], that is, 50 [kcall] is dissipated per ρ, and in the case of a generator output of 1.0OOKW, first converting the generator output into a heat amount is 1°000x86
0=860.000 [kcal/h, this is calculated as the heat dissipated from water per door (50x1.0OO=50.0OO
(kcal), it turns out that 17.2 [foot] of water is required per IFR interval. If you use this for 8 hours, you will need 17.2 x 8 balls of water, 140 [circumstances]□.

Ensuring this level of quality is in itself an office job, and as mentioned above, when using the water resistor (α), water must be removed from the water tank (C), the frame from which the water resistor (α) is hung, and the water tank. Since the equipment is large and requires pumps and piping, it takes a great deal of effort to transport and assemble them.

In addition, since the conductivity of water changes depending on the amount of impurities it contains, the water resistor (α) has the disadvantage that a stable resistance value cannot be obtained.

A further serious drawback is that when a water resistor (α) is used, a large amount of heated waste water is generated. This is because if we conduct a load test on a 1,000 kW generator in an urban area under the above conditions, and discharge heated wastewater at 70°C into the sewer at 17.2 [ends/h], it will not work, regardless of the drainage capacity. The lagoon would overflow, and even if it didn't overflow, the warm water would kill bacteria, reducing the sewage purification function, and sewage management may prohibit load tests.

As a load device used to measure the characteristics of a generator, water resistors have the disadvantages of being at risk of arcing, requiring a large amount of water, requiring extensive equipment and labor, and having unstable resistance values. It has various problems, including the generation of a large amount of heated waste water.

[Problems to be Solved by the Invention] However, the inventor of the present invention has found that although water is used as resistance, arcing is difficult to occur, no hot water is generated, the amount of water used is small, and the labor required for transportation and installation is low. The purpose of this invention is to create a load device system that can obtain at least a stable resistance value, and in particular, the present invention aims to provide a water resistor that is highly safe and does not cause arcing, and is used in this load device system. It is something to do.

Embodiments of the water resistor of the present invention and the electrode water treatment device for supplying water thereto will be described with reference to FIGS. 1 to 4.

The water resistor of the present invention (A> has a water supply hole (1) in the middle part of the side wall.
In addition, a drain hole (2) is drilled in the bottom of the base electrode (3), which is a cylindrical shape with a bottom and stores a predetermined amount of water inside. A cylindrical main electrode (6) is installed vertically at the lower end of which connects the output cable (5) of the generator, and the main electrode (6) is suspended so as to be movable up and down in order to adjust the exposed length of the main electrode (6). An insulating sheath tube (
7).

The water resistor (A) is one in Figures 1 to 4, but it is a set of three, and each main electrode (6) connects one of the three phases of the generator, while the base The electrodes (3) are interconnected and grounded. Therefore, it becomes a Y-connected resistor.

The one shown in FIG. 1 is for high voltage and small current. The one for low voltage and large current differs in that the diameter of the main electrode (6) is about the same as that of the main electrode (6), and the gap between it and the base electrode (3) is small.

Electrode water station 1 that cools the discharged water from this water resistor (A) and sends it in again! I! The device (B) is a radiator (
8), a spray pipe (9) that blows water onto the radiator (8) from the rear, a fan (10) that blows air from behind the spray pipe (9), and the fan (10),
Radiator (8) A louver (11) that guides the output sent to the front of the radiator (8) and disperses it into the upper space, and the radiator (8)
from the spray pipe (9) to the radiator (8).
Recovered water 41 (1
2) and a storage tank (13) in which water circulating between the water resistor (A) and the radiator (8) is stored in advance, as shown below.

That is, water stored in a water storage tank (13) is pumped up by a pure water pump (15) from a water suction pipe (14) vertically installed in the water, and filters (16) (17) and a water purifier (1
8) and then supply the water to the radiator (8) through the pure water filling pipe (19) and the lower discharge port (8a) of the radiator (8). ) to the water resistor (A) and the hot water discharged from the water resistor (A) is sent to the upper inlet (8b) of the radiator (8) by an interposed pump (20). ) and the cooling coil (22
) while cooling the pure water filling pipe (19) again.
A flushing return pipe (23) for returning to the water, a suction pipe (14) vertically installed in the water storage tank (13) with an interposed spray pump (24), and a suction pipe vertically installed in the recovery water tank (12). A spray water supply pipe (26) that pumps up water from either one of the pipes (25) and sends it to the spray pipe (9) is connected to the system via a switchable switching valve (27>(28) and (29)). be.

In Figure 1, (30) is the fan motor, (31), (32), and (33) are the fan motors (30).
), a pure water pump (15), a speed controller for the spray pump (24), and (34) a cooling coil.

[Operation] The operation of the entire load system configured as described above will be described first.

First, as shown by the arrow in Fig. 2, purified water passes through the suction pipe (14) and the pure water filling pipe (19) to the radiator (
8) and fills the water resistor (A>. That is, the water sucked up from the water storage tank (13) by the pure water pump (15) passes through the pure water pump (15) and then flows into the cooling coil (
34), filter (16) removes sand, etc., enters the filter (17), removes chlorine, and sends it to the water purifier (1).
Enter 8). The conductivity at this time is about 200 for ordinary tap water.
[μs/cm], which is used in a water purifier (18)
This decreases to approximately 1 [μS/cm 2 ]. When this is supplied to the radiator (8), at this point the electrode water pump (2
0) is not operating, water is filled into the C water resistor (A) through the cooling circulation pipe (21) from both directions as shown by the arrows.

This completes the water filling process, but the electrode water pump (20
), if impurities are dissolved and the conductivity becomes high, drain the water once and repeat the process 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, use the switching valves (28) and (29) to fill the pure water pipe (19).
After closing the electrode water pump (20), the filled water is pumped into the cooling circulation pipe (21) as shown by the arrow in Figure 3.
circulate inside.

At the same time, the spray pump (24) is activated, and water is sucked up from the water storage tank (13) with the suction pipe (14) as shown by the arrow in Fig. 3, passed through the spray pipe (26), and then transferred from the spray pipe (9) to the radiator ( 8) Direct the spray as shown by the dotted line. Meanwhile, fan motor (30)
Turn on the fan (10) and turn the radiator (8).
Air is blown from the back side.

Therefore, while passing through the water resistor (A), the water consumes electricity as a resistance, becomes dry, and is sent to the radiator (8), but this hot water is mixed with the water sprayed while passing through the radiator (8). It is cooled down. 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) and evaporates, and is sent out by the air blown from the back of the radiator (8) and the front of the radiator (8). It is blown up and diffused above the electrode water cooling device (B) as shown by the dotted arrow along the guide plate (11a) of the louver (11) disposed in the louver (11). Thereafter, the water cooled by the radiator (8) is again supplied to the water resistor (, A).

Water that is not completely evaporated by the water sprayed to cool 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 recovery water tank (12) is close to the full water level, the switching valve (27) is switched and the water in the recovery tank (12) is sucked up by the spray pump (24) through the suction pipe (25) and the spray pipe (9). You can send it to

If you want to lower the conductivity of the circulating water during operation, switch the switching valve (28>(29)) to direct the water to the flushing return pipe (23) and the pure water filling pipe as shown by the arrow in Figure 4. Road (1
). That is, water is discharged from the radiator (8), passes through the cooling coil (22), and is sent to the cooling coil (34) by the pure water pump (15).
Furthermore, since the water passes through the filters (16), (17) and M water trays and returns to the radiator (8), foreign matter and chlorine are removed and the conductivity decreases.

In this way, the load system created by Uninvented Part 1 does not generate heated waste water, but rather releases and diffuses the heat into the air as steam. Also, since heat is taken away through evaporation, it has a heat dissipation capacity equivalent to the latent heat of evaporation of water (560 kcal/ρ), which is about 11 times (560150?11) compared to the hot water discharge method described above. . Therefore, the required amount of water is only about 1/10, considering the water scattering loss.

Here, the action of the water resistor (A>) of the present invention will be described.

The water resistor (A) of the present invention has a cylindrical base electrode (3) and a main electrode (6), so there is little potential distortion, theoretically it is difficult to cause arc discharge, and there is no local protrusion. Therefore, the shape makes it difficult to cause arc discharge. Furthermore, an insulating sheath tube (7
), it is possible to freely adjust the length of the main electrode (6) underwater and adjust the power consumption, and in the event of a runaway phenomenon in which an arc is generated due to a rise in the temperature of the water, the insulating sheath tube ( It also has an emergency braking function that quickly stops the arc by lowering the electrode 7) to near the bottom of the main electrode (6).

In addition, with conventional water resistors including water tanks, the water tank and resistor had to be assembled each time they were used, and the process of mowing the water tank was quite labor intensive, requiring 5 to 6 people to assemble. On the other hand, the water resistor (A) of the present invention is preassembled in the shape shown in the drawings, and only two people are required to install and handle it, resulting in significant labor savings.

[Effects] As described above, the water resistor of the present invention is used in a load device system that does not generate hot water discharge, and is easier to handle than conventional water resistors that require a large number of people to assemble. It is simple and labor-saving, and has a compact design that does not take up much installation space.As it consists of a cylindrical base electrode and main electrode, arc discharge is less likely to occur, and power consumption can be adjusted by providing an insulating sheath tube (7) that can be moved up and down. It has extremely excellent effects on safety and workability, such as being able to perform emergency braking in the event of a runaway situation.

[Brief explanation of the drawing]

1 to 4 are explanatory diagrams of a water resistor A of the present invention and an electrode water treatment device B connected to the water resistor A, respectively.
The figure is a perspective view of a conventional water resistor. A... Water resistor B... Electrode water treatment device α・
...Water resistor a...High voltage cable b...Electrode plate C...Water tank 1...Water supply hole
2...Stain 1 Water hole 3...Base electrode 4...Insulator 5...Output cable 6...Main electrode 7...Insulation sheath tube 8...Radiator 8a...Drain hole
8b...Injection hole 9...Spray pipe 1
0...Fan 11...Garage 12...
Recovery water tank 13... Storage tank 14... Suction pipe 15... Pure water pump 16.17... Filter 18... Pure water device 19... Pure water filling pipe 20... Pump 21 ...Cooling circulation pipe 2
2... Cooling coil 23... Flushing return line 24... Spray pump 25... Suction pipe 26...
・Spray water pipes 27, 28.29...Switching valve 30...Fan motor 31.32.33...Speed controller 34...Cooling coil

Claims (1)

[Claims] 1. A cylindrical base electrode with a bottom that stores a predetermined amount of water inside with a water supply hole and a drainage hole, and an insulator that penetrates through the center of the bottom of the base electrode. A cylindrical main electrode that is installed vertically and connects the output cable of the power supply device to the lower end of the main electrode.
A water resistor 2 consisting of an insulating sheath tube that is suspended so as to be movable up and down to adjust the exposed length of the main electrode and covers the main electrode, and the main electrode has a small diameter when the main electrode has a high voltage and a small current. The water resistor 3 according to claim 1, in which the main electrode has a large diameter for low voltage and large current water resistor 4 according to claim 1, when the generator is multiphase, The water resistance according to claim 1, 2 or 3, which comprises a main electrode covered with an insulating sheath tube whose exposed length can be adjusted freely, and a large number of base electrodes extending through the center of the inner bottom. vessel