KR20160002193A - Dynamo system for testing micro water turbing generator - Google Patents

Abstract

Disclosed is a dynamo system for testing a micro water turbine generator. The system of the present invention comprises: a water pressure test device of which a micro water turbine generator enters the water; a flow valve to adjust an amount of water flowing into the water pressure device; and a pneumatic device to adjust pressure in the water pressure device.

Description

{DYNAMO SYSTEM FOR TESTING MICRO WATER TURBING GENERATOR}

The present invention relates to a dynamo system for testing a micro-airstream generator.

Generally, a dynamo system is used to test the generator. 1 is a block diagram for explaining a conventional dynamo system for testing a generator.

As shown in the drawing, a conventional dynamo system for testing a micro-aberration generator includes a test micro-auric generator 1 and a drive motor 10, an inverter 11 for motor control, a power analyzer 12, And a load resistor 13. With this structure, it is possible to check general electric use and efficiency of the output performance of the generator 15.

However, in the conventional dynamo system having the structure as shown in Fig. 1, since the micro-aberration generator 1 is immersed in water, there is a problem that insulation is destroyed by water pressure. The hydraulic test of the micro-aberration generator 1 is a test of the important items of the insulation test of the generator 1, and when the insulation breaks down, it can lead to a very dangerous situation in terms of human and material, It may also cause component failure.

Further, in the conventional dynamo system, it is difficult to analyze the temperature characteristic due to the long-time operation or to verify the maximum power point tracking algorithm in the power conversion apparatus. If these temperature characteristics and the maximum power point tracking algorithm are not verified, there is a limit to increase the lifetime and utilization of the system.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a dynamo system for testing a micro-aberration generator under actual use conditions in consideration of the characteristics and system of a micro-aberration generator.

In order to solve the above-described problems, a dynamo system of the present invention for driving a micro-aberration generator to be tested with a drive motor controlled by an inverter includes a hydraulic test apparatus in which the micro-airstream generator is obtained; A flow rate valve for adjusting the amount of water flowing into the hydraulic test apparatus; And a pneumatic device for regulating the pressure in the hydraulic testing device.

In one embodiment of the present invention, the hydrostatic test apparatus may be configured such that the micro-aeration generator has a size such that water can be completely locked, and the upper portion thereof can be configured to be openable and closable.

The system of an embodiment of the present invention may further include a grid-connected inverter that regenerates power consumed by the micro-aberration generator.

The system of an embodiment of the present invention may further include a thermometer side for measuring an operating temperature and a saturation temperature of the micro-aberration generator.

In one embodiment of the present invention, the thermometer side part can measure the temperature of the grid interconnected inverter.

The system of an embodiment of the present invention may further include a control unit for torque-controlling the inverter using output-speed and torque-speed data of the micro-aberration generator.

In an embodiment of the present invention, the control unit can receive the output of the drive motor driven by the inverter and verify the maximum power point tracking algorithm.

According to another aspect of the present invention, there is provided a dynamo system for testing a micro-aberration generator, including: a driving motor for driving the micro-aeration generator; An inverter for receiving a commercial power supply and controlling the drive motor; A hydrostatic test device in which the micro-aberration generator is obtained; A flow rate valve for adjusting the amount of water flowing into the hydraulic test apparatus; A pneumatic device for regulating the pressure in the hydraulic test apparatus; A grid-connected inverter for regenerating power consumed by the micro-aberration generator to a commercial power source; A thermometer side part for measuring an operating temperature and a saturation temperature of the micro-aberration generator; And a controller for torque-controlling the inverter using output-speed and torque-speed data of the micro-aberration generator.

The present invention as described above has the effect of securing the stability of the micro-aberration generator by testing the micro-aberration generator under actual use conditions.

The life of the micro-aero generators depends on the degree of saturation of the temperature under the use conditions. The present invention is capable of performing the temperature saturation test under special conditions, In addition, since the grid-connected inverters used therefor can regenerate the consumed electric power, there is an economically advantageous effect.

In addition, since the maximum power point tracking algorithm can be verified using the maximum power point tracking (MTTP) curve data, the present invention has an effect of improving the utilization rate of the micro aberration generator and ultimately increasing the power generation amount.

1 is a block diagram for explaining a conventional dynamo system for testing a generator.
2 is a diagram illustrating a dynamo system for testing a micro-aberration generator according to an embodiment of the present invention.
3 is a graph showing output-velocity and torque-velocity data of a runner blade of a micro-aberration generator.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating a dynamo system for testing a micro-aberration generator according to an embodiment of the present invention.

The dynamo system of one embodiment of the present invention includes a hydraulic test apparatus 2 connected to a flow valve 21 and a pneumatic device 22 and a hydraulic test apparatus 2 connected to a thermometer side 54 and a grid- Device (3).

In the dynamo system of the present invention, the control inverter 11 receives a commercial power supply to control the drive motor 10, and the drive motor 10 drives the micro- A coupling portion 52 is disposed between the generator 1, the torque sensor 51, the speed reducer 53, and the drive motor 10 so that they can be connected to each other.

The water pressure test apparatus 2 is formed to have a size of, for example, a width × height × height of 1.5 m and a lower portion connected to the flow rate valve 21 to fill the micro- And a structure capable of discharging water after the test. The pneumatic device 22 can be connected to the hydraulic test apparatus 2 for a hydraulic pressure condition that meets the conditions of actual use of the generator 1. That is, the flow rate valve 21 is configured to regulate the amount of water available to the water pressure testing apparatus 2, and the air pressure apparatus 22 can be configured to regulate the pressure in the water pressure testing apparatus 2.

The hydraulic test apparatus 2 is configured to be directly connected to a test bed 7 of the dynamo system and is formed so that the upper portion thereof can be opened and closed so that the test airstream generator 1 can be easily attached or detached. In addition, the portion to be bonded for maintaining the pressure may be constituted by attaching rubber or gasket facilities.

The temperature measuring unit 54 measures the temperature of the water pressure test apparatus 2 under the actual conditions of use of the generator 1. The water pressure test apparatus 2 includes a chiller ). The temperature measuring unit 54 can measure the temperature of the drive motor 10 in addition to the temperature of the generator 1.

Thus, the temperature measuring unit 54 is configured to measure the operating temperature and the saturation temperature with respect to the use environment of the generator 1, and it is easy to select the type of windings of the generator 1 through the temperature test, . Conventionally, the load resistor 13 is used for measuring the temperature of the generator 1, but the method using the load resistor 13 converts the consumed power into heat and has a problem that power consumption is very large .

In order to solve the above problems while using the load resistance 13 as it is, the present invention can constitute a dynamo system including the grid-connected inverter 3 so as to regenerate power consumed from the generator 1 have.

That is, the generator 1 of the present invention can be connected to either the resistive load 13 or the grid interconnected inverter 3 via the switch 6, and when connected to the grid interconnected inverter 3, It is possible to regenerate the electric power generated by the electric motor 1 and transmit the electric power to the system to regenerate the consumed electric power. At this time, the thermometer side portion 54 may monitor the overheating of the inverter 3 by receiving the temperature data from the grid interconnect type inverter 3. [

Thus, the consumption power of the dynamo system of the present invention can be lowered to less than 10% of the system capacity.

On the other hand, the control unit 14 of the conventional dynamo system of Fig. 1 receives data from the resistance load 13, the power analyzer 12 and the drive motor control inverter 11 via communication, There is a problem that the tracking algorithm can not be verified.

In order to verify the maximum power point tracking algorithm, the control unit 4 of the present invention is designed to solve the above-described problems by using the output-speed data of the runner blade (not shown) of the micro- The maximum power point tracking algorithm can be verified by storing the torque-speed data and torque-controlling the control inverter 11 using the torque-speed data.

3 is a graph showing output-velocity and torque-velocity data of a runner blade of a micro-aberration generator.

3, A denotes output-speed data and B denotes torque-speed data. The control unit 4 controls the torque of the control inverter 11 using this data, and controls the torque of the inverter 11 according to the torque control of the inverter 11 By receiving the output of the generator 1 driven through the drive motor 10 through the torque / speed amplifier 55, the maximum power point tracking algorithm can be verified. Such data may be stored in the control unit 4 in advance, or may be provided from outside via communication.

On the other hand, the torque / speed amplifier 55 receives the torque and the speed from the torque sensor 51 connected to the generator 1, and the temperature measuring section 54 receives, in addition to the generator 1 and the drive motor 10, The temperature of the speed reducer 53 connected between the inverter 1 and the drive motor 10 and also receives the temperature of the grid interconnected inverter 3 and transmits the overall temperature of the system to the control unit 4 .

The control unit 4 can receive the temperature data of at least one of the generator 1, the drive motor 10, the speed reducer 53 and the grid interconnected inverter 3 from the thermometer side 54, It is possible to receive power conversion related data from the inverter 3 and perform overall control, measurement and analysis on the system. The control unit 4 may be, for example, a personal computer (PC), but is not limited thereto, and various devices may be used.

As described above, the present invention can be applied to a hydraulic test apparatus 2 that can connect the flow rate valve 21 and the pneumatic device 22 and can contain the generator 1 in consideration of special operating conditions of the micro- So that the main pressure condition of the applied head height can be controlled through the flow valve 21 and the pneumatic device 22.

Accordingly, it is possible to perform a test to determine whether or not the micro-aberration generator 1 is in actual use condition, by measuring the insulation against abnormality in the bearing portion or the cable connecting portion have.

The grid-connected inverter (3) of the present invention further includes a temperature saturation test by the continuous operation test of the micro-aberration generator (1) for a long time and a verification of a maximum power point tracking algorithm for improving the utilization rate of the generator Can be performed.

Generally, the temperature saturation test of the generator 1 is performed for 10 hours or more, and the output test by the conventional load resistance has a large cost for power consumption in the case of the continuous test for a long time like this. However, ), It is possible to reduce the consumed power to 10% of the magnetic capacity.

The control unit 4 of the present invention stores the maximum power point control (MTTP) curve data of the runner blades of the generator 1 in advance, performs torque control of the control inverter 11 based on the stored maximum power point control (MTTP) curve data, The maximum power point can be tracked by confirming the output through the speed amplifier 55 and the overall efficiency and utilization of the turbine generator 1 can be improved in this manner.

According to the present invention as described above, the stability of the micro-aberration generator 1 can be secured by testing the micro-aberration generator 1 under actual use conditions.

The life of the micro-airstream generator 1 depends on the degree of saturation of the temperature under use conditions. The present invention can be applied to a temperature saturation test under special conditions, And the grid interconnected inverter 3 used therefor is economically advantageous because power consumed can be regenerated.

In addition, since the maximum power point tracking algorithm can be verified by using the maximum power point tracking (MTTP) curve data, the utilization rate of the micro aberration generator 1 can be improved and finally the power generation amount can be increased.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

1: Micro-airstream generator 10: Drive motor
11: Control inverter 12: Power analyzer
13: resistive load 2: hydraulic test device
21: Flow valve 22: Pneumatic device
3: Grid-connected inverter 4:
51: torque sensor 52: coupling part
53: Reducer 54: Temperature measuring unit
55: Torque / speed amplifier 6: Switch
7: Test Bed

Claims (8)

A dynamo system for driving a micro-aberration generator to be tested with a drive motor controlled by an inverter,
A hydrostatic test device in which the micro-aberration generator is obtained;
A flow rate valve for adjusting the amount of water flowing into the hydraulic test apparatus; And
And a pneumatic device for regulating the pressure in the hydraulic test apparatus.
The hydraulic test apparatus according to claim 1,
Wherein the micro-aberration generator is configured such that the water can be fully submerged, and the upper portion thereof is configured to be openable and closable.
The method according to claim 1,
Further comprising a grid-connected inverter that regenerates power consumed by the micro-aberration generator.
The method of claim 3,
And a thermometer side for measuring an operating temperature and a saturation temperature of the micro-aberration generator.
5. The system of claim 4,
A dynamo system for measuring the temperature of the grid interconnected inverter.
The method according to claim 1,
Further comprising a control unit for torque-controlling the inverter using output-speed and torque-speed data of the micro-aberration generator.
7. The apparatus of claim 6,
And receiving the output of the drive motor driven by the inverter to verify a maximum power point tracking algorithm.
In a dynamo system for testing a micro-airstream generator,
A drive motor for driving the micro aberration generator;
An inverter for receiving a commercial power supply and controlling the drive motor;
A hydrostatic test device in which the micro-aberration generator is obtained;
A flow rate valve for adjusting the amount of water flowing into the hydraulic test apparatus;
A pneumatic device for regulating the pressure in the hydraulic test apparatus;
A grid-connected inverter for regenerating power consumed by the micro-aberration generator to a commercial power source;
A thermometer side part for measuring an operating temperature and a saturation temperature of the micro-aberration generator; And
And a control unit for torque-controlling the inverter using output-speed and torque-speed data of the micro-aberration generator.

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