RU100332U1 - HIGH VOLTAGE POWER SYSTEM - Google Patents

Abstract

 1. A high-voltage power supply system containing an adjustable power source based on high-frequency converters, a protective key block, a control system, a voltage sensor and a current sensor, the outputs of which are connected to the corresponding inputs of the control system, while one of its outputs is connected to a control input of the adjustable power source and the other with the input of the protective key unit, characterized in that an unregulated power source operating at the frequency of the mains, which alone of its outputs connected to a controlled source, and the other - with the protective unit keys and voltage sensor unit. ! 2. The high voltage power supply system according to claim 1, characterized in that the unregulated high voltage source is made on the basis of one or more switching devices, one or more transformers, one or more rectifiers, one or more capacitors. ! 3. The ratio of power and voltage between regulated and unregulated sources to the output power of the system can be different depending on the specific task. ! 4. In addition, the block of protective keys can be excluded and the output of an unregulated power supply will be the output of the system.

Description

The invention relates to the field of instrumentation, in particular to power supply systems, protection and control of technological installations, as well as power supply systems for microwave generator devices, such as klystrons, traveling and backward-wave lamps, magnetrons, gyrotrons, etc. The technical problem is to improve overall performance, increased efficiency and reliability.

Of the many known high-voltage power supply systems, the invention closest to the utility model is the invention “High-voltage power supply system (options) and an electronic key for it” (RU 2315387, publ. 2008.01.20), in which the high-voltage power supply system contains a power supply, a control system, a voltage sensor, a current sensor, a protective key block, while one of the inputs of the protective key block is connected to the first bus of the power supply, and the other input is connected to one of the outputs of the control system, the second bus of the power supply via a current sensor is connected to a common bus, and the output of the current sensor is connected to the first input of the control system, the second input of which is connected to the output of the voltage sensor, and the output of the protective key block is the output of the system.

In addition, the power supply includes a primary power source, at least two bridge resonant transformers, two high-frequency transformers, two rectifiers, two filters, while one of the inputs of each bridge resonant converter is connected to the output of the primary power source, and the other to the corresponding output of the control system, while the output of each resonant converter is connected to the input of the corresponding high-frequency transformer, the outputs of which are ineny appropriate rectifiers to the inputs and outputs of the rectifiers are connected to the inputs of the respective filters, wherein each filter output is connected to a corresponding input of addition circuit whose output is connected to the first bus of the power supply source coupled via a voltage sensor with a common bus.

In addition, bridge resonant converters are connected in parallel to each other.

In addition, the output of each bridge resonant converter through a resonant circuit, consisting of at least one inductance and one capacitance, connected in series, is connected to the input of the high-frequency transformer.

In addition, the addition scheme is made in the form of a parallel connection of filters.

In addition, the addition scheme is made in the form of a series connection of filters.

In addition, the block of protective keys is made in the form of N electronic keys based on field insulated gate or insulated gate bipolar transistors connected in series with each other.

The disadvantage of this invention is the large dimensions of the installation for an autonomous system when powering the device from a three-phase network of 220 V, 400 Hz and power more than 5 kW, since the latter consists of numerous parallel and series connection of both structurally complete modules and individual semiconductor components at the output voltage over 2000 V. The increased conversion frequency of transistor resonant converters, of the order of (20-100) kHz, involves working with the electromagnetic component from ferrite materials having small dimensions, however, this is poorly combined with ensuring insulation strength when operating at high voltages higher than 10 kV, and heat dissipation, which reduces the reliability and efficiency of the system.

This invention is the closest analogue of the proposed utility model, i.e. prototype.

The objective of the proposed utility model is to increase efficiency, reduce dimensions and increase reliability by transforming most of the power and voltage at the mains frequency of 400 Hz.

The problem is solved by creating a high-voltage power supply system containing an adjustable power supply based on n high-frequency converters, a protective key block, an adjustable source control system, as well as a current sensor and a voltage sensor, which are connected with their outputs to the corresponding inputs of the control system, while one of the outputs of the control system are connected to the input of the protective key unit, and the other to the control input of an adjustable power supply, one from the output poles of which, through a current sensor, is connected to a common busbar, and the other is additionally inserted and connected in series at the output, and parallel to the input, by an unregulated power supply operating at a mains frequency, while the other pole of an unregulated power supply is connected to a voltage sensor and through a block of security keys with a load.

In addition, an unregulated power source may consist of one or more switching devices, one or more transformers, one or more rectifiers, one or more capacitors.

In addition, the security key block may be omitted, and the output of the unregulated power supply will be the output of the system.

The utility model is illustrated by the drawings:

Figure 1 shows the structural diagram of a high voltage power supply system.

Figure 2 shows an electrical diagram of a power unregulated power source operating at a network frequency of 400 Hz.

The high-voltage power supply system (Fig. 1) contains a power unregulated source operating at the frequency of the power supply network 1, a regulated power source based on n high-frequency converters 2, connected in parallel to the input, and in series, with a high-potential output, the unregulated power source 1 is connected to voltage sensor 4 and the block of protective keys 6, the control input of which is connected to one of the outputs of the control system 5, and its other output is connected to the control input of the power adjustable of source 2, the respective inputs of the control system 5 are connected to the output of the voltage sensor 4 and the output of the current sensor 3, and the low-potential power output controlled source 1 is connected through the current sensor 3 to the common bus.

In addition, the power unregulated power supply 1 introduced (figure 2) two contactors k1, k2 with separate control, two transformers T1, T2 and two bridge rectifiers connected in series at the output, assembled on high-voltage poles V1 ... V12, while the inputs transformers T1, T2 through the corresponding contactors K1, K2 are connected to the primary network.

In an example of a utility model, the system was mocked up based on the development of a prototype high-voltage power supply based on high-frequency converters assembled using powerful key high-speed MOS transistors, for example, SPW47N60C3, as well as bipolar transistors with an insulated gate, for example, IRGP50B60PD1 and control drivers for them Type: HCPL 3120, HCPL 5200, IR2113S.

To produce a high-frequency, high-voltage transformer-rectifier module, a PK40 * 25 ferrite core of the 2500NMS7 grade and high-voltage high-frequency diodes of type 2D215D1 and capacitors of type K15-20V-3 kV were used.

Power unregulated. the part was assembled from domestic components and materials, such as self-made high-voltage transformers of electrical steel grade 3424, high-voltage poles of type 2TS203V and capacitor of type K75-29B.

High voltage power system operates as follows.

The entire system is powered from the primary power network 220 V, 400 Hz, 3 phases, the voltage of which is supplied to the auxiliary power supply (SIP) and to the inputs of power sources 1 and 2. At the same time, the control system 5 generates a command to turn on the protective key block 6 for connecting the high voltage system to the load when the first and for the second stage via contactors k1 and k2 (2) an unregulated power source 1, the high voltage output system appears 2/3 U _O of the output voltage. In this embodiment, the output voltage of an unregulated power supply 1 is 2/3 U _o ; the output power of the power sources is in the same ratio. In this case, the output windings of the transformers T1 and T2 of FIG. 2 are made: one with a star, and the other with a triangle for receiving. 12 times ripple in the output voltage of a power unregulated source. Thus, the ripple frequency of the output voltage of an unregulated power source, determined by the coefficient of the circuit and the input frequency of the network, is:

400 Hz * 12 = 4800 Hz.

Moreover, the ripple coefficient _{K1 of the} twelve phase circuit is 1.4%, which is important when choosing the filter capacity rating.

Then, upon a command from the control system 5, a regulated power supply is turned on, and the output voltage of the high-voltage system gradually increases, reaching its nominal value U _o and its stabilization point, since negative feedback from the voltage sensor 4, which through the control device 5 begins to act on the adjustable part of the circuit. In this case, if the voltage value of the network changes, for example, by ± 5%, the voltage at the output of the unregulated part of the circuit will also change, in which case the regulated power source will compensate for the difference.

The output voltage of the system can be adjusted by about 1/3, since the adjustable part of the circuit is designed for 1/3 of the output power and 1/3 of the output voltage. The ratio of power and output voltage of power sources can be any, depending on the task.

In case of current overload or K.Z. in the load, the current sensor 3 generates a signal that enters the control system 5 and it gives a signal to disable or block the protective keys 6, or turns off the power sources 1, 2.

The instability of the output voltage of the proposed system when exposed to all destabilizing factors is fixed at the same level of ± 2%, as in the case, building it at full power based on high-frequency converters in the prototype.

Such a construction of a high-voltage system allows the use of an adjustable source for part of the output voltage and output power, for example, 10 kV and 10 kW instead of 30 kV and 30 kW, which significantly unloads the most vulnerable part of the semiconductor circuit, made on field or bipolar transistors connected in parallel and sequentially. At the same time, the requirements for insulation strength to the high-frequency, high-voltage transformer-rectifier module, which is performed on ferrite cores and has a minimum size, are reduced, which makes it difficult to provide the necessary insulation strength in combination with heat dissipation.

Thus, the creation of the proposed high-voltage power supply system can improve reliability and improve overall dimensions.

The next positive point is that the high-voltage power supply system based on high-frequency converters has an efficiency value of 85-86%, while the unregulated part of the power source operating at a network frequency of 400 Hz has an efficiency of 95-97%. Thus, the more power will be converted due to the unregulated part of the circuit, the greater the efficiency value will be for the entire system, in this case the efficiency value will be about 90%.

The same can be said about the overall performance of a high-voltage power supply system based on high-frequency converters, which has specific characteristics (85 V - 100) t / dm ³ , while an unregulated power source operating at a network frequency of 400 Hz has specific characteristics at the level of 614 W / dm ³ (1), which allows us to conclude that the overall dimensions of the system are reduced if most of its power is converted using an unregulated power source.

References: Berezin O.K., Kostikov V.G., Shakhnov V.A.

Power sources of electronic equipment. - M.: “Three L”, 2000.-400 p.

Claims (4)

1. A high-voltage power supply system containing an adjustable power source based on high-frequency converters, a protective key block, a control system, a voltage sensor and a current sensor, the outputs of which are connected to the corresponding inputs of the control system, while one of its outputs is connected to a control input of the adjustable power source and the other with the input of the protective key unit, characterized in that an unregulated power source operating at the frequency of the mains, which alone of its outputs connected to a controlled source, and the other - with the protective unit keys and voltage sensor unit. 2. The high voltage power supply system according to claim 1, characterized in that the unregulated high voltage source is made on the basis of one or more switching devices, one or more transformers, one or more rectifiers, one or more capacitors. 3. The ratio of power and voltage between regulated and unregulated sources to the output power of the system can be different depending on the specific task. 4. In addition, the block of protective keys can be excluded and the output of an unregulated power supply will be the output of the system.