ES1112180U - Power control device in electrical network (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Power network control device (1) characterized in that it comprises: - a transformer which in turn comprises: - a secondary winding which in turn is connected in series with a load of the installation and which comprises an output connected to the network, and - a primary winding comprising three inputs, two of said inputs corresponding to 0, and connected to the output of the secondary winding for feedback of the primary winding, and - a power control module (2) comprising: - a control element connected for its supply to the output of the secondary winding and having at least one voltage output connected to a trigger plate, which controls a tripping of at least one electronic control module (2) of power intended for to control an rms voltage applied to the primary winding, and - at least one relay, which is connected to neutral (5) and with at least one of its outputs connected to two inputs of the three inputs of the primary winding, where said two of three inputs are those inputs corresponding to 0. (Machine-translation by Google Translate, not legally binding)

Description

OBJECT OF THE INVENTION

The present invention relates to a network control device intended for three-phase and single-phase installations.

More specifically, the invention is framed in the field of control of the electrical network, especially in tasks of stabilization of the grid voltage, filtering of electrical noises, to avoid voltage spikes, and attenuation of transient overcurrent peaks.

BACKGROUND OF THE INVENTION

Society and industry present a large number of electronic equipment of various generations, such as those linked to process control, operation, data processing, communications and information transmission, domestic, commercial and entertainment devices.

On the other hand, the widespread and progressive use of alternative sources of renewable energy, such as wind and solar, makes use of generators with inverters with hybrid schemes in many cases connected to distribution networks. The necessary conversion process always involves an eventual generation of harmonics.

An insufficient quality in the supply of electric energy affects, to a greater or lesser extent, other technologies and industrial processes, where the economic losses generated by this concept can become very important. In this sense, with voltage parameters other than nominal or working, there is an acceleration of the aging of the insulation of electrical equipment as a result of intensive heating and, in a series of cases, as a result of the strengthening of ionization processes; All this results in an intensification of the failure rates.

Also, electric voltage deviations lead to an increase in the heating of electric motors with constant moments of load (load type conveyor, elevator etc.), accelerating the aging of the insulation, and a waste of energy. For example, a rise in voltage above the nominal voltage leads to a decrease in the lifetime of lamps and a higher consumption that can lead to breakdowns or an increase in operation and maintenance costs that, in the end, result in End customer with large losses.

On the other hand, asymmetry in tension also leads to additional heating of the force equipment and decreases its useful life and increases consumption. This defect also negatively influences the operation of some relay protection schemes, causing erratic operations and causing a malfunction of equipment powered by electrical energy. The appearance of rapid variations in the asymmetry of the three-phase voltages entails the variation of the torque moments in the electric motors, which is the cause of the appearance of additional efforts on the heads of the machine coils, their vibration and fatigue stresses in constructive mechanical elements of the motor itself and the drive, which results in a decrease in its life time and considerable consumption peaks.

Voltage variations act differently on different types of electrical equipment. For example, in capacitor banks used for reactive power compensation, it causes transient processes that lead to capacitor overload by current and, in cases, by voltage, as a result of which the battery may be taken out of service, where the period it takes for the battery to go from service to out of service may be more or less long depending on the magnitude of the disturbance: the larger the magnitude, the shorter the period.

In the case of motors, voltage variations lead to additional heating and moment variation with respect to the axis. Voltage dips for asynchronous motors tend to slow them down and require any re-starting processes, and may lead to situations of protection tripping, especially when working with motor groups simultaneously.

DESCRIPTION OF THE INVENTION

The present invention relates to an electrical power network control device in an installation whose load comes from said network. The control device described here has a specific transformer and a network check circuit, which acts connected between one input or another of the primary winding of the transformer and controls the voltage with a single set of power electronics and eliminates the need to use several sets of semiconductors at the same time that is applicable to any type of transformers in addition to being able to control the voltage volt by volt and not by programmed steps.

The device object of the invention allows to control the totality of the intensity applied by acting on a percentage thereof, allowing the possible receiving devices that feed on it to consume the power they really have to consume, nominal or close, and thus lengthen The shelf life of them.

The purpose of the present invention is to be able to adjust the mains voltage to a much more stable range with the possibility of adjusting the mains voltage with a very small margin of error, in the order of millivolts.

The device of the following invention ensures that the power and / or voltage of the electrical network entering an installation is completely stable, in addition to reducing a large percentage of incoming noise, produced by the large number of electronic systems connected to the power networks. distribution.

In a preferred embodiment, the device described herein makes use of at least one "booster" type stabilizer and semiconductor-based power control means that once installed can be checked and managed the network input of any installation, to later control it and adjust it to the indicated parameters.

In a more preferred embodiment, the possibility of adding an output control component to check and check the output of the device to the installation is also contemplated; so that the circuit operation can be adjusted or modified, or even canceled, if the control component has to show data that requires it, such as low values that are not useful for the electrical installation at the input of which is connected the output of the device object of the invention.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of practical implementation thereof, a set of drawings is attached as an integral part of said description. where, for illustrative and non-limiting purposes, the following has been represented:

FIG. 1 Shows a diagram of the "booster" type stabilizer. FIG. 2 Shows a circuit diagram based on semiconductors used for management And control. FIG. 3 Shows a graph showing the regulation of applied power. FIG. 4 Shows a diagram of the device object of the invention.

PREFERRED EMBODIMENT OF THE INVENTION

Next, a detailed example of a preferred embodiment of the present invention is described with the aid of the aforementioned figures, based on tests carried out by the inventors, which show the effectiveness of the device for power control in the electrical network of the invention.

In a preferred embodiment of the device (1) for power control in the electrical network of the invention, as shown in Figures 1 and 2, the power control device (1) of the electrical network object of the invention has to be The invention makes use of a "booster" type stabilizing circuit as shown in Figure 1. In this type of stabilizer, the total current of a load does not circulate through the switching elements (which a preferred embodiment of the invention are Triacs), but only a proportional fraction of it circulates.

When an eventual elevation or reduction of input voltage (7), which is associated with an electromagnetic switch (5), takes place in a transformer whose secondary winding is in series with the line and the load, a regulation of output voltage (8) by varying the voltage of a primary winding of said transformer.

The transformer's own inductance can act as an attenuation factor in reducing possible line noise and transient peaks.

To be able to control and manage the electrical energy of the device (1), use is made of a phase angle adjustment that is based on the possibility of being able to make a connection of the mains voltage at any point of the half-wave in a synchronized manner. In this way, the sinusoidal voltage can be "trimmed" into smaller sectors, which allows the power applied to the load to be regulated at last. As can be seen in Figure 3, it is necessary that each sinusoidal half wave of the network corresponds to a conduction of 180º (360º for a complete cycle), so that, by delaying the connection from 180º to 0º, the power applied to The load from 0 to 100%. This delay value at the phase angle is called the "delay angle" and is usually indicated by the letter a (alpha). In some cases we also talk about the «driving angle», which corresponds to the 180º-a value.

In this sense, it is necessary that the management device (1) described herein comprises said transformer, with a transformation ratio from 2/1 to 30/1, depending on the need, and whose secondary winding is arranged in series with a loading of the installation in which the device (1) is installed, and with a primary winding comprising three inputs, two of said inputs corresponding to 0, and which is fed back from an output of the secondary winding, which is connected to the net; where the primary winding has three connections with the following relation: 0-n- -0, where n varies between 20 V and 30 V and where, depending on the neutral (5) that is connected, represented by "0" in the relation previously indicated, we will have a tension in the secondary winding proportional with respect to the input voltage (7).

Said phase feedback of the primary winding is controlled by at least one electronic power control module (2) comprising a set of thyristors, preferably at least two thyristors arranged in antiparallel, commanded by a thyristor firing plate capable of work from 0 to 10V; said trigger plate is in turn controlled by the power control module (2) additionally designed to read in real time the input signal (7) of the mains, and thus control the control voltage of the board of firing of the semiconductors, being able to control the

5 100% of the input signal (7).

The power control module (2) is an electronic power control module (2) intended to control an RMS voltage applied to the primary winding and comprises a control element connected for feeding to an output of the secondary winding, and 10 has at least one of its voltage outputs connected to the trip plate which controls the firing of at least one thyristor of the control module; The power control module (2) also has at least one relay which is connected to neutral (5) and with at least one of its outputs connected to two inputs of the three inputs that the primary winding has, those corresponding inputs to 0. These relays are responsible for connecting or disconnecting 0 of the primary to neutral winding as needed to increase or decrease voltage as it is convenient at all times, or to modify the voltage by raising or lowering. As shown in Figure 2, the control module

(2) can be found associated with a shutdown element (9) intended to turn off the device (1) or the control module (2) when it is determined that the voltage is

20 sufficiently above or below respective predetermined upper and lower voltage thresholds.

Finally, it is possible to have a voltage reading module (11) located before the output (8) and intended to read the voltage that is sent to the installation

25 to verify it or to make adjustments to the control if it is not the desired one.

In a possible alternative embodiment of the invention, a series of filters against electrical noise (3) and a series of filters against transient peaks (4), filters (3,4) that are arranged in parallel and respectively connected can be arranged to neutral (5) and

30 to ground (6).

Claims (3)

 R E I V I N D I C A C I O N E S 1.- Power control device (1) in a power grid characterized by comprising:

-

a transformer that in turn comprises:

5 - a secondary winding which in turn is connected in series with a load of the installation and comprising an output connected to the network, and

-

a primary winding comprising three inputs, two of said inputs corresponding to 0, and connected to the output of the secondary winding for feedback of the primary winding, and

10 - a power control module (2) comprising:

-

a control element connected for feeding to the output of the secondary winding and having at least one voltage output connected to a trip plate, which controls a trip of at least one electronic power control module (2) intended for control an RMS voltage applied to the primary winding, and

15 -at least one relay, which is connected to neutral (5) and with at least one of its outputs connected to two inputs of the three inputs of the primary winding, where said two of three inputs are those corresponding to 0. 2. Device (1) according to claim 1, characterized in that the transformer has a transformation ratio between 2/1 and 30/1. 3. Device (1) according to claim 1 or 2, characterized in that the primary winding comprises a series of connections with a 0-n-0 ratio, n being a value between 20 V and 30 V. 4. Device (1) according to any one of the preceding claims, characterized in that the power control module (2) comprises at least two thyristors arranged in antiparallel.