RU2225668C1 - No-break power supply unit - Google Patents

Abstract

FIELD: power engineering; no-break dc and ac auxiliary power systems for nuclear power plants. SUBSTANCE: no-break power supply unit that has three-phase mains, three-phase rectifier, diesel-generator set, input selector switch, storage battery, dc buses, first and second inverters, and ac buses is provided in addition with dc voltage regulator and one more three- phase rectifier; storage battery has first and second leads, first one being connected to plus terminal of three-phase rectifier through first and second electronic switches and second lead, to dc plus bus through third electronic switch whose output is connected to dc plus bus and to plus output of dc voltage regulator; output of first inverter is connected to both inputs of second inverter with aid of current transformer, rectifier, L-shaped filter incorporating choke and capacitor, ac buses being connected to outputs of both inverters; second inverter is connected to dc plus bus through fourth electronic switch and to minus bus, directly; mentioned electronic switches are built around diodes. EFFECT: enhanced reliability and voltage stability across buses. 3 cl, 4 dwg, 1 tbl

Description

 The invention relates to the field of electric power and can be used in uninterruptible power supply units (UPS) of the auxiliary needs of power plants, as well as in critical drives of direct and alternating current.

 A UPS is known that contains the main source - an industrial network and a backup source - a diesel generator unit, connected via the first automatic transfer switch (ATS) to common buses, to which an auxiliary load, a rectifier and communication equipment connected via the second ATS are connected directly at the same time, a battery is connected to the output of the rectifier, and an inverter is connected to the connection points of the rectifier and the specified battery, the output of which is connected to the equipment through the second ABP e connection [1]. This UPS has buses for guaranteed power supply of direct and alternating current consumers, which led to its wide distribution in various fields of technology, however, all switching in the UPS circuit is carried out by electromechanical switches with significant inertia, therefore, in the places of connecting consumers there are interruptions in the power supply, the duration of which is determined by time operation of switches.

 The closest in technical essence to the claimed one is a UPS containing 220 V DC power buses, to which a three-phase network and a diesel generator unit are alternately connected through a three-phase rectifier, a battery and two inverters, to the outputs of which AC buses are connected via thyristor switches 0 , 4 kV [2]. This UPS is characterized by high performance, since all the keys are electronic and uninterrupted supply of direct and alternating current consumers, but it also has drawbacks, among which the main ones are relatively low reliability, since the unit has only one three-phase rectifier with two alternating voltage sources, and low voltage quality on all tires due to the lack of stabilizers of both direct and alternating current, as well as the complexity of the unit circuit due to the application thyristor keys.

 The technical result of the invention is to increase the reliability of the device and the stability of the voltage on its tires due to the introduction of an additional three-phase rectifier and DC voltage stabilizer.

 The technical result is achieved by the fact that the device containing the findings for connecting a three-phase network, a diesel generator unit, a battery, the main three-phase rectifier, DC bus, input switch, the first and second three-phase inverters and three-phase alternating current bus connected to the outputs these three-phase inverters, and the common output of the battery is connected to the negative DC bus, the plus and negative terminals of the first three-phase inverter are connected to the corresponding positive and negative DC buses, and the negative terminal of the second three-phase inverter is connected to the negative DC bus, a DC voltage stabilizer is introduced, the input of which is connected to the output of the main three-phase rectifier, and the output to DC buses, four electronic keys and an additional three-phase a rectifier, while the positive terminal of the additional three-phase rectifier is connected to the input of the first electronic switch, the output of which is connected to the positive terminal of the main phase rectifier, and the negative terminals of the main and additional three-phase rectifiers are interconnected, the battery contains two groups of sections, the negative terminals of these groups are combined to form a common battery terminal, and the plus terminals of these groups are the first and second plus terminals of the battery, respectively, the first the positive terminal of the battery is connected to the input of the second electronic key, the output of which is connected to the input of the first electronic key, the second the positive terminal of the battery is connected to the input of the third electronic key, the output of which is connected to the positive DC bus, the positive terminal of the second three-phase inverter is connected to the output of the fourth electronic key, the input of which is connected to the positive DC bus, to the output circuit of one of the phases of the first three-phase inverter the primary winding of the current transformer is connected in series, the secondary winding of which is connected to the input of the rectifier unit, the output of which is connected through the L-shaped filter with the input of the second three-phase inverter formed by the plus and minus terminals of the specified inverter, the input switch contains two three-phase inputs and two three-phase outputs, while its first and second three-phase inputs are connected to the terminals for connecting the three-phase network and the output terminals of the diesel generator unit, respectively, and the first and second three-phase outputs - with inputs of the main and additional three-phase rectifiers, respectively, the contacts of the input switch are designed to close the corresponding al his first three-phase input and output at a first state input switch, circuit its respective phases of second-phase input and output at a second state and disconnecting switch input phases of said three phase inputs and outputs in the third state input switch.

 In addition, each of the electronic keys is made in the form of a diode, the anode of which is the input of the electronic key, and the cathode is the output.

 In addition, the input switch contains a relay of the first, second and third phases, each of which contains an NC contact, and two of these relays contain NO contacts, in addition, a voltage monitoring relay with three-phase NO contacts and a network status relay with power three-phase NO contacts and three-phase make contacts, while the relay windings of the first, second and third phases are connected between the corresponding phase of the first three-phase input and the neutral wire, the winding of the mains voltage monitoring relay is on on between one of the phases of the first three-phase input and the neutral wire through the relay contacts of the other two phases connected in series, the winding of the network status relay is connected between one of the phases of the second three-phase input and the neutral wire through the relay contacts of the first second and third phases connected in parallel three-phase make contacts of the network voltage monitoring relay and power three-phase make contacts of the network status relay are connected in phase sequence between the corresponding phases of the first and of the three-phase inputs, the phases of the first output through the opening contacts of the corresponding phases of the network status relay are connected to the common terminals of the corresponding phases of the closing contacts of the network voltage monitoring relay and the power closing contacts of the network status relay, and the phases of the second three-phase output are connected to the mentioned common conclusions of the corresponding phases of the indicated contacts three-phase make contacts of a relay of a condition of a network.

 Figure 1 presents a circuit diagram of an uninterruptible power supply unit; figure 2 is a timing diagram of the formation of voltage on the DC bus 220 V; figure 3 is a diagram of the conclusions of the battery; figure 4 is an example of the implementation of the input switch.

 The uninterruptible power supply unit (Fig. 1) contains a three-phase network 1, a diesel generator unit 2 connected to a three-phase network 1 through a three-phase input switch 3, a battery 4, a main three-phase rectifier 5 connected by an input to a three-phase network 1 through a switch 3, buses 6 (6-1 and 6-2) of direct current, the first 7 and second 8 inverters and bus 9 of alternating three-phase current, and the common terminal 10 of the battery 4 is connected to the negative bus 6-2 DC, plus and minus terminals of the first inverter 7 connected to corresponding busbars 6 (6-1 and 6-2) of direct current. The minus clamp of the second inverter 8 is connected to the negative DC bus 6-2, the DC stabilizer 11 is connected between the output of the main three-phase rectifier 5 and the DC bus 6, an additional three-phase rectifier 12 is connected by an input to the output of the input switch 3. The first and second three-phase inputs of the switch 3 are connected to a three-phase network and the output terminals of the diesel generator unit 2, respectively. In this case, the positive terminal of the additional three-phase rectifier 12 is connected to the positive terminal of the main three-phase rectifier 5 through the first electronic key 13, and the negative terminal of the additional three-phase rectifier 12 is connected to the negative terminal of the main three-phase rectifier 5 directly, the first positive terminal 14 of the battery 4 is connected to the input of the first the electronic key 13 through the second electronic key 16, the second positive terminal 15 of the battery 4 is connected to the input of the third electronic key 17, the output to torogo connected with the positive DC bus 6-1. The positive clamp of the second inverter 8 is connected to the positive DC bus 6-1 through the fourth electronic key 18, the primary winding of the current transformer 19, the secondary winding of which is connected to the input of the rectifier unit 20, the output of which is L-shaped, is sequentially connected to the output circuit of the first inverter 7 the filter 21, consisting of a inductor 22 and a capacitor 23, is connected to the input of the second inverter 8. The first output of the inductor 22 is connected to the positive output of the rectifier unit 20, the second output of the inductor 22 is connected to the positive m the output of the capacitor 23 and the output of the fourth electronic key 18 connected to the plus terminal of the input of the inverter 8, and the negative terminal of the capacitor 23 is connected to the negative terminal of the rectifier unit 20 and the negative terminal of the input of the inverter 8. Electronic keys (EC) 13, 16, 17 and 18 made in the form of diodes, the anodes of which are inputs of electronic keys, and the cathodes are outputs.

 The input switch 3 (Fig. 4) contains a phase A relay 25, the winding of which is connected between the phase A of the network and the neutral wire and having a breaker contact 25-1, phase B relay 26, whose winding is connected between the phase of the network B and the neutral wire and having a disconnect contact 26-1 and make contact 26-2, relay 27 of phase C, the winding of which is connected between phase C and the neutral wire and having break contact 27-1 and make contact 27-2, relay 28 for monitoring the mains voltage with make power contacts 28- 1 and relay 29 network status with NC 29-2 and circuit contacts 29-1 and 29-3, while the winding of the relay 28 monitoring the mains voltage is connected between phase A of the network and the neutral wire through series-connected make contacts 26-2 and 27-2 of the relay phase B and C, and the coil of relay 29 of the network status is connected between the phase C 'of the diesel generator 2 and the neutral wire through the disconnecting contacts 25-1, 26-1 and 27-1 of the relay 25, 26 and 27 of the phase relay A, B and C, connected in parallel with each other.

 The closing contacts 28-1 and 29-1 are made three-phase and connected in phase between the outputs of the corresponding phases of the network and the output of the diesel generator unit 2. The input terminals of the main three-phase rectifier 5 through three-phase disconnecting contacts 29-2 of the relay 29 of the network status are connected to the common conclusions of the closing pins 28-1 and 29-1 of the respective phases. The output terminals of the additional three-phase rectifier 12 are connected to the common terminals of the make contacts 28-1 and 29-1 of the corresponding phases through three-phase make contacts 29-3 of the network status relay 29.

 Elements 24 (Fig. 3) of the battery 4 in a charged state are assembled in sections (not shown), the positive terminals 14 and 15 of which are used during UPS operation, and the negative terminals of these sections are connected and form a common terminal 10.

 The uninterruptible power supply unit operates as follows.

 In the static mode, all sources of electricity (Fig. 1) are a three-phase network 1, the diesel generator unit 2 and the battery 4 are disconnected, and there are no voltages on the DC bus 6 and the AC bus 9, therefore, all DC and AC consumers (not shown in figure 1) de-energized. Elements of the uninterruptible power supply unit: input 3 switch, main 5 and additional 12 three-phase rectifiers are de-energized, electronic keys 13, 16, 17 and 18 are closed, the DC voltage regulator 11 is not working, the first 7 and second 8 inverters are not working, the current transformer 19 is not working , and the signal on its secondary winding is absent, the rectifier unit 20 is inoperative, there is no signal at the input of the L-shaped filter 21, and the capacitor 23 is discharged, the relay 25, 26 and 27 phases (Fig. 4) and the relay 28 of the control voltage of the switch 3 inputs are de-energized, barely 29 is de-energized state of the network, the cells 24 of the battery 4 charged and collected in two sections with the positive terminal 14 and 15 (Figure 4) and the common negative terminal 10.

 In the main mode of operation of the UPS, the three-phase network 1 is turned on, and the voltage of the industrial frequency is supplied to the input of the main three-phase rectifier 5, where it is reduced in amplitude and rectified, while the rectified voltage is supplied to the input of the constant voltage regulator 11, where it is stabilized in magnitude, and stabilized DC voltage from the output of the specified stabilizer is supplied to the negative 6-1 and positive 6-2 DC buses 6, to which DC consumers are connected (the process of Ia voltage busbar DC shown in Figure 2). If there is voltage on the DC bus 6, the first inverter 7 is turned on, and the voltage used to power the AC consumers (not shown in Fig. 1) appears on the busbars 9 of the alternating three-phase voltage. Due to the fact that the start of the first inverter 7 is carried out almost instantly, a signal proportional to the load current, which is rectified in the rectifier unit 20, is removed from the secondary winding of the current transformer 19, filtered by a L-shaped filter 21 and fed to the terminals of the second inverter 8, closing the fourth electronic key 18, therefore, the specified inverter does not work (when the inverter 7 is running). In this mode of operation of the UPS, the first electronic key 13 is always locked. In the event of a malfunction or when the three-phase network 1 is disconnected, the UPS operates in standby mode, while the diesel generator unit 2 is started, the electric power of which is supplied through an input switch 3 to an additional three-phase rectifier 12, where the voltage decreases in amplitude, is rectified and supplied through an open electronic switch 13 the input of the stabilizer 11 constant voltage. Further, the UPS operates according to an algorithm similar to the main mode, while the second electronic key 16 will be locked. The turn-on time of the diesel generator unit 2 and the DC bus power 6 depend on it depending on the input switch 3, an additional three-phase rectifier 12, and a DC voltage stabilizer 11. The input switch 3 is a circuit for automatically switching on the reserve, described, for example, in [1], which has input buses, a voltage monitoring circuit for them, and redundant buses with its own voltage monitoring circuit, and the load will be connected to the buses of that monitoring circuit, which works faster, that is, the input switch 3 performs the functions of an OR logic circuit, performed, for example, on electromechanical elements.

 One of the specific circuits of the input switches 3 contains (Fig. 4) a phase A relay 25 with an open contact 25-1, a phase B relay 26 with an open contact 26-1, a phase C relay 27 with an open contact 27-1 and a voltage control relay 28 a network connected in series with the closing contacts 26-2 and 27-2 of the phase B and C relays. With a functioning three-phase network 1, all of these relays are activated and the relay 28 for monitoring the network voltage with its closing power contacts 28-1 connects the main three-phase rectifier 5 to the three-phase network 1 (terminals A, B and C). In case of a faulty three-phase network 1, the network status relay 29 will operate and with its closing power contacts 29-1 connects the voltage of the diesel generator unit 2 (terminals A ', B' and C ') to the input of the additional three-phase rectifier 12, closing contacts 29-3 and opening the contacts 29-2 located at the input of the main three-phase rectifier 5. Thus, with a working three-phase network 1, the diesel generator unit 2 can be in a hot reserve, which ensures uninterrupted formation of DC busbars 6 of the uninterruptible unit Ethan.

 In the third emergency mode, the operation of the UPS is carried out in two stages: using a stabilizer 11 constant voltage and without the specified stabilizer. In this case, at the first stage, when the three-phase network 1 and the diesel generator unit 2 are disconnected, the battery 4 is discharged first along the circuit: the first positive terminal 14, the second electronic switch 16, the first electronic switch 13, the stabilizer 11 constant voltage, the positive bus 6-2 constant current, internal resistance of direct current consumers, negative busbar 6-1 direct current, the overall output of the battery 4. With a sufficiently deep discharge of the elements 24 of the battery 4 (figure 3), the voltage on the DC bus 6 decreases and open The third electronic key 17 is used, with which the voltage is added (the number of elements 24 of the battery 4 is increased, as shown in FIG. 4) and the battery 4 is discharged in a circuit: the second positive terminal 15 of the battery 4, the third electronic key 17, the positive bus 6-2 DC, internal resistance of direct current consumers, negative bus 6-1 DC, common terminal 10 of the battery 4.

The operation of both inverters 7 and 8 at these stages of the discharge of the battery 4 is similar to their operation in the main mode (when powered by a three-phase network). The states of the main elements of the uninterruptible power supply unit circuit are indicated in the table, from which it follows that in all modes on DC buses 6 and AC buses 9 there are always voltages of a given value, while the voltage on DC buses 6 is determined by the inequalities
U _c > U _dga , U _dga > U ₁₅ , U ₁₅ > U ₁₄ ,
where U _c is the constant voltage received from the three-phase network;
U _dga - constant voltage received from the diesel generator unit;
U ₁₄ is a constant voltage received from the first positive terminal 14 of the battery 4;
U ₁₅ - DC voltage received from the second positive terminal 15 of the battery 4.

The voltage value on the time interval t _c (network operating time) is equal to
U _c = U _nom + δU _y ,
where U _nom - rated voltage on the DC bus 6;
δU _y - steady-state voltage deviation.

The voltage value in the time interval t _dga (operating time of the diesel generator set) is equal to
U _dga = U _nom +1/2 δU _y
The voltage value in the interval t ₁₄ (the initial discharge time of the battery 4 is U ₁₄ = U _nom , and the voltage value in the interval t ₁₅ (the final discharge time of the battery 4) is
U ₁₅ = U _nom -1/2 δU _y
From the diagram in question (figure 2) it follows that the back-up voltages of electronic keys (EC) 13, 16 and 17 are: for the first electronic key 13 - U _c , for the second electronic key 16 - U _dga , and for the third electronic key 17 - U _nom.
Thus, the introduction of an additional three-phase rectifier 12, connected to the diesel generator unit 2, and the use of a battery with terminals 14 and 15 allows you to create voltage on the DC bus 6 in four circuits, which significantly increases the reliability of the device, and the inclusion of a stabilizer in the circuit 11 DC voltage eliminates surges and voltage dips on the power lines of DC consumers.

 The voltage generated by the current transformer 19, the rectifying unit 20, the L-shaped filter 21, is fed to the input of the second inverter 8 and allows three-phase current consumers to have a three-phase voltage that is stable in amplitude due to the specified stability of the inverter supply voltage, which achieves the desired result.

Sources taken into account
1. Power supply for communication devices. Ed. O.A. Domoratsky -M.: Radio and Communications, 1981, Fig. 8.9., P. 246.

 2. Zilberman VA, Relay protection of the auxiliary network of nuclear power plants, -M .: Energoatomizdat, 1992, Fig. 2, p. 10.4

Claims (3)

1. An uninterruptible power supply unit containing terminals for connecting a three-phase network, a diesel generator unit, a battery, a main three-phase rectifier, DC buses, an input switch, first and second three-phase inverters and three-phase alternating current buses connected to the outputs of these three-phase inverters, moreover, the common terminal of the battery is connected to the negative DC bus, the positive and negative terminals of the first three-phase inverter are connected to the corresponding positive and negative to the DC bus, and the negative terminal of the second three-phase inverter is connected to the negative DC bus, characterized in that a DC voltage stabilizer is introduced, the input of which is connected to the output of the main three-phase rectifier, and the output to the DC buses, four electronic keys and an additional three-phase a rectifier, while the positive terminal of the additional three-phase rectifier is connected to the input of the first electronic switch, the output of which is connected to the positive terminal of the main three-phase rectifier the negative terminals of the main and additional three-phase rectifiers are interconnected, the battery contains two groups of sections, the negative terminals of these groups are combined to form a common battery terminal, and the positive terminals of these groups are the first and second positive terminals of the battery, respectively, the first positive the battery terminal is connected to the input of the second electronic key, the output of which is connected to the input of the first electronic key, the second positive output the battery is connected to the input of the third electronic key, the output of which is connected to the positive DC bus, the positive terminal of the second three-phase inverter is connected to the output of the fourth electronic key, the input of which is connected to the positive DC bus, is connected in series to the output circuit of one of the phases of the first three-phase inverter the primary winding of the current transformer, the secondary winding of which is connected to the input of the rectifier unit, the output of which is connected to the input of the second through a L-shaped filter of the three-phase inverter formed by the plus and minus terminals of the specified inverter, the input switch contains two three-phase inputs and two three-phase outputs, while its first and second three-phase inputs are connected to the terminals for connecting the three-phase network and the output terminals of the diesel generator unit, respectively, and the first and the second three-phase outputs - with inputs of the main and additional three-phase rectifiers, respectively, the contacts of the input switch are designed to close the corresponding phases of its first rehfaznyh input and output state at the first input switch, circuit its respective phases of second-phase input and output at a second state and disconnecting switch input phases of said three phase inputs and outputs in the third state input switch. 2. The uninterruptible power supply unit according to claim 1, characterized in that each of the electronic keys is made in the form of a diode, the anode of which is the input of the electronic key, and the cathode is the output. 3. The unit according to claim 1 or 2, characterized in that the input switch contains a relay of the first, second and third phases, each of which contains an NC contact, and two of these relays contain NO contacts, in addition, a voltage monitoring relay with three-phase make contacts and network status relays with power three-phase make contacts and three-phase make contacts, while the relay windings of the first, second and third phases are connected between the corresponding phase of the first three-phase input and the neutral wire, relay winding the voltage monitoring of the network is connected between one of the phases of the first three-phase input and the neutral wire through the relay contacts of the other two phases connected in series, the winding of the network status relay is connected between one of the phases of the second three-phase input and the neutral wire through the relay contacts of the first, second and the third phase, the three-phase make contacts of the network voltage monitoring relay and the three-phase power make contacts of the network status relay are connected in phase in series between by the corresponding phases of the first and second three-phase inputs, the phases of the first output through the opening contacts of the corresponding phases of the network status relay are connected to the common terminals of the corresponding phases of the closing contacts of the network voltage monitoring relay and power closing contacts of the network status relay, and the phases of the second three-phase output are connected to the mentioned general conclusions of the corresponding phases of these contacts through three-phase make contacts of the network status relay.

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