RU144509U1 - CONVERTER WITH 24X AC RATING VOLTAGE FREQUENCY - Google Patents

Abstract

A converter with a 24-fold AC to DC ripple frequency, containing two three-phase transformer sources, the primary windings of which are connected in an "unequal zigzag", creating a phase shift of 15 el. degrees between transformers, and the secondary windings on each transformer rod have only two values of the number of turns, connected on each transformer to each other in a star and a triangle, characterized in that the connection of the secondary windings of both transformers are connected to two six-phase ring rectification circuits that are interconnected successively by three parallel valve cells, each cell is formed by three valves, the anodes of which are interconnected, forming three anode groups, which are are connected to the terminals of the source of the first ring rectification circuit x, y, z, the cathodes of these valve groups are cross-connected, forming three cathode groups that are connected to the terminals of the source of the second ring rectification circuit a, b, c, the bipolar conclusions of the ring rectification circuits form output conclusions devices.

Description

The utility model relates to electrical engineering and power converting equipment and can be used as an AC voltage to DC high voltage converter to supply traction loads of electric vehicles and to obtain high voltages for direct current power lines.

A known converter with a 24-fold alternating-voltage pulsating frequency to a constant voltage, containing a three-phase transformer, the primary windings of which are connected in a star or a triangle, and the secondary windings having four values of the number of turns create four three-phase sources that are connected to four three-phase rectifier bridges connected in series (A S. USSR USSR No. 1638779, IPC H02M 7/12, publ. March 30, 1991, Bull. No. 12).

The disadvantage of this converter is its relatively low efficiency due to power losses at eight valves sequentially streamlined by the load current.

Closest to the utility model adopted for the prototype is a converter with a 24-fold frequency of alternating voltage to DC voltage, containing two three-phase transformer sources, the primary windings of which are connected in an "unequal zigzag" creating a phase shift of 15 el. degrees between transformers, and the secondary windings of each transformer having two values of the number of turns are connected into a star and a triangle, the linear voltages of which from the respective transformers are applied to four series-connected three-phase rectifier bridges (Pat. RF No. 91486, IPC H02M 7/08 2006/01 published on 02/10/2010).

The disadvantage of this converter is its relatively low efficiency due to power losses at eight valves sequentially streamlined by the load current.

The objective of the utility model is to create a converter with a 24-fold frequency of ripple of an alternating voltage to a constant, having a higher efficiency.

This problem is achieved by the fact that in the known Converter with a 24-fold frequency of the ripple of the alternating voltage to constant, containing two three-phase transformer sources, the primary windings of which are connected in an "unequal zigzag" creating a phase shift of 15 el. degrees between transformers, and the secondary windings on each transformer rod have only two values of the number of turns, connected on each transformer to each other in a star and a triangle, characterized in that the connection of the secondary windings of both transformers are connected to two six-phase ring rectification circuits that are interconnected successively by three parallel valve cells, each cell is formed by three valves whose anodes are interconnected to form three anode groups which are dineny conclusions first annular circuit rectifying x power, y, z cathodes of the rectifier groups interconnected by cross forming three cathode groups are connected to the output of the supply of the second annular circuit rectifying a _1, b _1, c ₁ and bipolar conclusions annular rectifying circuits form the output device leads.

In FIG. 1 shows a diagram of the proposed Converter with a 24-fold frequency of the ripple of the alternating voltage to constant.

In FIG. Figure 2 shows the amplitude-phase portraits of the voltages of the secondary phase windings forming the resulting voltage.

A converter with a 24-fold alternating-to-DC ripple frequency (Fig. 1) contains two three-phase transformers 1 and 2 forming two six-phase EMF systems, represented by the outputs of sources a, b, c; x, y, z and a ₁ , b ₁ , c ₁ ; x ₁ , y ₁ , z ₁ phase-shifted by fifteen electrical degrees, as well as twenty-seven valves 3 ... 29, of which two six-phase ring rectification circuits are formed, valves 3 ... 11 constitute the first ring rectification circuit, and valves 21 ... 29 make up the second ring rectification circuit, these circuits are interconnected by three parallel valve cells consisting of valves 12 ... 20, the valves of one circular rectification circuit 3, 4, 5 are interconnected by anodes forming an anode group, and the cathodes are connected to the terminals and the achnik a, b, c, and the gates 6 ... 11 form an annular group of gates which are connected in pairs with the anodes 6 and 9, 7 and 10, 8 and 11 with the terminals of the source a, b, c, respectively, and their cathodes are pairwise 7 and 11, 8 and 9, 6 and 10, are connected to the terminals of the source x, y, z, respectively, the valves of another ring circuit, the valves 27, 28, 29 are interconnected by cathodes forming a cathode group, and the anodes are connected to the terminals of the source x ₁ , y ₁ , z ₁ valves 21 ... 26 form an annular group of valves which are pairwise anodes 21 and 24, 22 and 25, 23 and 26 are connected to source terminals a _1, b _1, c _1, respectively, and their cat dy pairs 22 and 26, 23 and 24, 21 and 25 are respectively connected to terminals source x _1, y _1, z ₁ a series connection of ring circuits straightening interconnected is provided with three parallel gating cells, each cell is formed by three gates their anodes connected together and the valves 12, 13, 14 form the first anode group; the second valves 15, 16, 17. and the third valves 18, 19, 20 which are connected to the terminals of the source of the first ring rectification circuit y, z, x, respectively, the cathodes of these valve groups are interconnected crosswise by three valves and form the first cathode group of the valves 14 , 16, 18 the second valves 12, 17, 19 and the third valves 13, 15, 20 which are connected to the terminals of the source of the second ring rectification circuit a ₁ , b ₁ , c _1, respectively. Common points 30 and 32 of the connection of the valves of the anode and cathode groups, respectively, of the first and second ring rectification circuits form the output terminals of the converter, to which the load 31 is connected.

The principle of operation of the converter (Fig. 1) is based on a two-stage series-connected circuit, each stage contains a six-phase symmetric EMF system and a rectification rectifier circuit. Transformers 1; 2, create two six-phase symmetric EMF systems whose primary windings consist of two parts of the network and phase-shifting with the ratio of the number of turns 1: accordingly, their connection with each other according to the scheme "unequal treatment zigzag" creates a phase shift of 15 e. degrees between six-phase symmetric systems formed by the secondary windings of transformers, which are placed two on each transformer rod with a ratio of the number of turns equal to , the interconnection of three windings having a larger number of turns in a triangle, and three windings having a smaller number of turns in a star creates the equality of the values of the linear voltages added from the phase voltages and an equal phase shift of 30 el. degrees. An illustration of the converter operation is displayed by vector voltage diagrams presented in the form of amplitude-phase portraits of the voltage of phase windings that make up two six-phase voltage systems of groups of secondary windings and vector diagrams deployed on the phase plane explaining the principle of formation of the resulting voltages represented by vectors S1 ... S24 (Fig. 2).

Vector diagrams (Fig. 2) show the amplitude-phase characteristics of each of the six-phase EMF systems used. The ratio of the number of turns of the secondary phase windings equal and phase shift voltages of 15 el. degrees between six-phase symmetric systems provides dynamic formation of the resulting stresses, the vectors of which are equal and shifted relative to each other on the phase plane by 15 el. hail. Conventionally fixing the vector diagram of the voltages of one system and moving around it the vector diagram of the voltages of another system, for the period of the mains voltage we get 24 vectors of the resulting voltages (Fig. 2). In each position of the systems on the phase plane, the elements of valve connections are determined, the sequence of operation of the secondary windings and valves, which are summarized in the table.

Table Ripple Line Voltage Indices Valve numbers S1 -ca ∗ z → -c ₁ a ₁ ∗ z ₁ 5, 6, 15, 18, 26 S2 -ca ∗ z → -c ₁ a ₁ ∗ y ₁ 5, 6, 15, 21, 25 S3 -ca ∗ y → -c ₁ a ₁ ∗ z ₁ 5, 9, 13, 18, 26 S4 -ca ∗ y → -c ₁ a ₁ ∗ y ₁ 5, 9, 13, 21, 25 S5 -cb ∗ x → -c ₁ b ₁ ∗ x ₁ 5, 7, 20, 19, 24 S6 -cb ∗ x → -c ₁ b ₁ ∗ z ₁ 5, 7, 20, 22, 26 S7 -cb ∗ z → -c ₁ b ₁ ∗ x ₁ 5, 10, 15, 19, 24 S8 -cb ∗ z → -c ₁ b ₁ ∗ z ₁ 5, 10, 15.22, 26 S9 -bc ∗ y → -b ₁ c ₁ ∗ y ₁ 4, 8, 12, 20, 25 S10 -bc ∗ y → -b ₁ c ₁ ∗ x ₁ 4, 8, 12, 23, 24 S11 -bc ∗ x → -b ₁ c ₁ ∗ y ₁ 4, 11, 19, 20, 25 S12 -bc ∗ x → -b ₁ c ₁ ∗ x ₁ 4, 11, 19, 23, 24 S13 -ba ∗ z → -b ₁ a ₁ ∗ z ₁ 4, 6, 17, 18, 26 S14 -ba ∗ z → -b ₁ a ₁ ∗ y ₁ 4, 6, 17, 21, 25 S15 -ba ∗ y → -b ₁ a ₁ ∗ z ₁ 4, 9, 12, 18, 26 S16 -ba ∗ y → -b ₁ a ₁ y ∗ y ₁ 4, 9, 12, 21, 25 S17 -ab ∗ x → -a ₁ b ₁ ∗ x ₁ 3, 7, 18, 19, 24

S18 -ab * x → -a ₁ b ₁ ∗ z ₁ 3, 7, 18, 22, 26 S19 -ab ∗ z → -a ₁ b ₁ ∗ x ₁ 3, 10, 16, 19, 24 S20 -ab ∗ z → -a ₁ b ₁ ∗ z ₁ 3, 10, 16, 22, 26 S21 -ac ∗ y → -a ₁ c ₁ ∗ y ₁ 3, 8, 14, 20, 25 S22 -ac ∗ y → -a ₁ c ₁ ∗ x ₁ 3, 8, 14, 23, 24 S23 -ac ∗ x → -a ₁ c ₁ ∗ y ₁ 3, 8, 18, 20, 25 S24 -ac ∗ x → -a ₁ c ₁ ∗ x ₁ 3, 8, 18, 23, 24

The study of the state of stress systems in time using vector diagrams (Fig. 2) allows us to determine the order of alternating operating intervals of six-phase symmetrical stress systems connected to the valve structure. For example, when generating the resulting voltage of the first ripple S1 specified in the first column of the table, the largest magnitude of the linear stress vectors added from the phase voltage vectors are ca ∗ z and c ₁ a ₁ ∗ z ₁ connected to the first and second ring rectification circuits, respectively. These indices of linear stresses are indicated in the second column of the table, and the third column shows the numbers of the valves turned on under the action of these voltages, valves 3 and 5 of the first ring rectification circuit, valve 15 connecting to the valves 18 and 26 of the second ring rectification circuit. The numbering of the valves on the circuit diagram (Fig. 1) corresponds to the order of their inclusion in the conversion process. Based on the valve switching algorithm shown in the table, with perfect switching at any time in the load current flow circuit, only five valves are connected in series.

The prototype valve rectification circuit consists of four three-phase bridge in series type, where at any moment in the circuit of the current flow eight valves are sequentially flowed around the load current. Compared with the prototype, the circuit-topological connections in the proposed scheme provide a reduction in the number of valves sequentially streamlined by the load current from eight valves to five. This is a technical result, which for consumers may turn out to be the best solution, since with high valve classes, power losses in the valve design can be reduced by 37%, thereby increasing the efficiency of the converter as a whole by no less than 0.37%.

Thus, the proposed Converter with a 24-fold frequency of the ripple of the alternating voltage to constant, has a higher efficiency compared to the prototype, due to the reduction of power losses associated with a reduction in the number of valves from eight valves to five successively streamlined loads.

Claims (1)

A converter with a 24-fold AC to DC ripple frequency, containing two three-phase transformer sources, the primary windings of which are connected in an "unequal zigzag", creating a phase shift of 15 el. degrees between transformers, and the secondary windings on each transformer rod have only two values of the number of turns, connected on each transformer to each other in a star and a triangle, characterized in that the connection of the secondary windings of both transformers are connected to two six-phase ring rectification circuits that are interconnected successively by three parallel valve cells, each cell is formed by three valves, the anodes of which are interconnected, forming three anode groups, which are are connected to the terminals of the source of the first ring rectification circuit x, y, z, the cathodes of these valve groups are connected crosswise to form three cathode groups, which are connected to the terminals of the source of the second ring rectification circuit a ₁ , b ₁ , c _1, and the bipolar ring conclusions rectification circuits form the output terminals of the device.