RU2059104C1 - Method of operation of small hydroelectric power station - Google Patents

Abstract

FIELD: hydraulic power engineering; generation of power by small hydroelectric power stations and microstations. SUBSTANCE: first brake torque of hydraulic set rotor is increased and then hydraulic set is started with electric load switched off and brake torque is changed until preset maximum tolerable speed of hydraulic set rotor is obtained. Then load is connected to generator and is changed to determine maximum tolerable value corresponding to maximum tolerable speed of hydraulic set rotor. Then hydroelectric power station is operated within range of load variations from zero to maximum tolerable. EFFECT: enlarged operating capabilities. 5 cl, 1 dwg

Description

 The present invention relates to hydropower and can be used to generate electricity at small or micro-hydroelectric stations (HPS).

 When generating electricity at hydroelectric power plants, it is necessary to maintain the rotational speed of the rotor of a hydraulic unit, consisting of a hydraulic turbine and an electric current generator connected to it, in a given range. This requirement is due to the fact that the voltage and frequency of the electric current are functions of the rotational speed of the rotor of the generator. To solve this problem, it is necessary to maintain the equality of the capacities of the consumer of electric current and the power generated by the electric generator.

 A known method of operating a hydroelectric power station in a given range of changes in the rotational speed of the rotor of a hydraulic unit, which consists in changing the power on the generator shaft depending on the power of the consumer by changing the power of the water flow entering the turbine connected to the generator. This method includes the use of a special regulatory body at the inlet of the guide turbine and a hydromechanical or electro-hydraulic regulator. This method is appropriate for medium and large power plants, but it is very expensive for small and micro hydro plants.

 There is also a method of operating small and micro hydroelectric power stations in a given range of changes in the rotational speed of the rotor of a hydraulic unit using an electric ballast load connected to an electric current generator adopted as a prototype. Using such a ballast load, the braking torque on the hydraulic unit shaft is changed. In operating modes, the controller sets the necessary opening of the guide vane, which corresponds to the optimal use of the watercourse, and all changes in the consumer load (below the optimum load of the hydraulic turbine) are absorbed by the ballast load (for example, by electrical resistances for heating water or heating). Ballast load control can be carried out either by the rheostat method or by pulsed switching of a constant load by thyristor switches. Thus, the constant equality of consumer power and the power of the electric current generated by the generator is maintained. The use of a guide apparatus in some cases can be completely excluded, which is an advantage of this method. However, the method includes the use of an electronic controller and electric ballast, which also makes its use for small and micro hydroelectric power plants very expensive and, moreover, operation reliability is reduced due to the complex design of the controller.

 A method is proposed for operating a small hydroelectric power station, including a hydraulic unit, consisting of a hydraulic turbine and an electric current generator connected to it, in a predetermined range of the rotational speed of the hydraulic unit rotor, which consists in first increasing the braking torque of the hydraulic unit rotor, then starting the hydraulic unit with the electric load switched off and changing braking torque until the specified maximum permissible rotor speed of the hydraulic unit is reached, after which it is connected to an electric generator load, change it and determine the maximum allowable value of the electric load corresponding to the minimum allowable rotational speed of the hydraulic unit rotor and then operate the hydroelectric power station in the range of change in electric load from zero to the maximum allowable. The braking torque of the rotor of the hydraulic unit can be increased by attaching a hydraulic brake to the hydraulic unit and changed, for example, by changing the degree of filling of the brake with water. The braking torque of the hydraulic unit rotor can be increased by attaching a mechanical brake to the hydraulic unit and changed, for example, by changing the tension of the brake band. The braking torque of the rotor of the hydraulic unit can be increased by attaching an induction brake to the hydraulic unit and changed, for example, by changing the magnitude of the excitation current of the inductor. The braking torque of the rotor of the hydraulic unit can be increased by attaching to the hydraulic unit of the pump, for example, a vortex, and changed by for example changing the flow of the pump.

 The technical result of the invention is the effect of self-regulation of hydraulic units, which allows to refuse in some cases the use of complex, expensive and unreliable regulators. This in turn can dramatically increase reliability, reduce operating costs and the cost of small hydropower plants.

The specified technical result is achieved by first increasing the braking torque of the rotor of the hydraulic unit by attaching any brake device to its shaft, for example, a hydraulic brake, which is one or more discs attached to the shaft and placed in a casing, the degree of filling of which with water can be regulated. Then, water is supplied to the turbine with the generator switched off. The rotor of the hydraulic unit begins to rotate. After that, the braking torque is successively changed by changing the degree of filling of the brake housing with water and the braking torque is experimentally selected at which the rotor of the hydraulic unit rotates with the maximum permissible frequency. After that, connect the electrical load and change it. With an increase in electrical load, the rotor of the hydraulic unit reduces the speed. By successively changing the electric load, determine its maximum permissible value at which the rotor of the hydraulic unit rotates with the minimum permissible frequency. A hydraulic brake attached to the rotor of the hydraulic unit changes its power N _t according to the law N _t ≈n ³ , where n is the rotation frequency. This leads to the fact that, for example, for a given acceptable range of changes in the rotational speed of the hydraulic unit rotor from 1950 to 1150 rpm (n ± 30% with a synchronous generator speed of n = 1500 rpm), the brake power changes approximately 2.2 times. Let, for example, a hydroturbine with an disconnected electric load develop a power of 30 kW, which is completely damped by a hydraulic brake at a rotor speed of n = 1950 rpm. When connecting to the generator of useful electric load, the rotor speed decreases and, accordingly, the power absorbed by the brake decreases by the value of the connected useful electric power. Self-regulation of the hydraulic unit. In this example, only due to the law N _t ≈n ^{3 a} small hydroelectric power station can be operated in the range of the change in the useful electric load from zero to about 14 kW without any regulator. In this case, the minimum rotational speed of the hydraulic unit rotor will be no less than the conditionally acceptable value n = 1150 rpm. The effect of self-regulation in some cases can be further increased due to the special characteristics of some hydraulic turbines and a rational choice of operating modes in which the turbine increases power as the rotational speed of the hydraulic unit rotates. This is due to an increase in the efficiency of the hydraulic turbine and an increase in the flow rate of water flowing through it with a decrease in the rotation frequency, i.e. as the payload increases.

 Similarly, you can use a mechanical or induction brake instead of a hydraulic one to increase the braking torque, or you can attach a pump, for example, of a vortex or centrifugal type, to the rotor of a hydraulic unit. When using a centrifugal pump and, in particular, a console centrifugal pump of type K290 / 30, the value of the braking torque is conveniently changed not only by changing the water supply, but by reducing (grooving) the diameter of the impeller.

 The proposed method is illustrated by the following example.

 The drawing shows the installation diagram comprising a hydraulic unit, consisting of a hydraulic turbine 1 with output 2 and input 3 nozzles, an electric generator 4 and a hydraulic brake 5 with input 6 and output 7 nozzles. The rotor of the hydraulic unit consists of a rotor of a hydraulic turbine 8 connected by means of a coupling 9 to a rotor 10 of an electric generator 4. The rotor 10 of an electric generator 4 is also connected by means of a coupling 11 to a rotor 12 of a hydraulic brake 5. An electric load is connected and disconnected from the electric generator (not shown conventionally in the diagram ) via cable 13.

 Installation works as follows. First, the braking torque of the hydraulic unit rotor is increased by attaching the hydraulic brake 5 to it using the clutch 11. Then, the hydraulic unit is started with the electric load switched off and the braking torque is changed by filling the hydraulic brake 5 with water. The water level in the brake is set by input 6 and output 7 water pipes. As the hydraulic brake 5 is filled with water, the braking torque of the hydraulic unit rotor increases, and decreases as it empties. In this case, the rotation speed decreases and increases accordingly. Changing the braking moment in this way, select its value that corresponds to the maximum permissible rotational speed of the hydraulic unit rotor. After that, the cable 13 connects the electric load to the electric current generator 4 and changes it by, for example, reducing or increasing the number of consumers. With an increase in electric load, the rotational speed of the hydraulic unit rotor will decrease, and with a decrease in electric load, it will increase. Changing the electrical load in this way, select its maximum allowable value, at which the rotor of the hydraulic unit rotates with the minimum allowable speed. After that, they operate a hydroelectric power station in the range of changes in electric load from zero to maximum.

 In all cases considered, the effect of self-regulation of hydraulic units will be ensured. The difference will only be in the different laws of changing the power of various braking devices or pumps from the speed, which will lead to different self-regulation efficiency.

Claims (5)

 1. METHOD OF OPERATION OF A SMALL HYDROPOWER PLANT containing a hydraulic unit in a predetermined range of changes in the rotational speed of the hydraulic unit rotor, including a change in torque on its shaft, characterized in that the braking torque of the hydraulic unit rotor is increased first, then the hydraulic unit is started with the electric load switched off and the braking torque is changed up to achieving the specified maximum permissible rotational speed of the hydraulic unit rotor, after which they connect an electric load to the generator, change it and determine the maximum admissible vylichinu electric load corresponding to the minimum permissible rotor speed hydraulic unit, and thereafter is operated in the range of HPP electrical load changes from zero to maximum.  2. The method according to p. 1, characterized in that the braking torque of the rotor of the hydraulic unit is increased by attaching a hydraulic brake to the hydraulic unit and changing it, for example, by changing the degree of filling of the brake with water.  3. The method according to p. 1, characterized in that the braking torque of the rotor of the hydraulic unit is increased by attaching a mechanical brake to the hydraulic unit and changing it, for example, by changing the tension of the brake band.  4. The method according to p. 1, characterized in that the braking torque of the rotor of the hydraulic unit is increased by attaching the induction brake to the hydraulic unit and changing it by, for example, changing the magnitude of the excitation current of the inductor.  5. The method according to p. 1, characterized in that the braking torque of the rotor of the hydraulic unit is increased by attaching to the hydraulic unit of the pump and change it by, for example, changing the volume of water flowing through the pump per unit time.

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