SU1198503A1 - System for supplying electric power to n loads - Google Patents

Abstract

The invention makes it possible to improve the weight and size characteristics of a power supply system (ESS) N of loads and to increase the reliability of its operation by reducing electromagnetic interference. The SC contains a primary voltage converter, the output of which is connected to the inputs of N secondary power sources (VIP). Each subsequent switching VIP consists of a regulating element 11, the control input of which is connected to the control unit 12, and an output filtering unit. Every VIP

Description

Pre-switching includes another current sensor 15 in the power bus. This effect is achieved by the introduction of (N - 1) matching nodes (SU), and the input of each SU is connected to the output of a current sensor 15

1198503

in the VIP of preliminary inclusion, and. the output is connected to the input of the control node of the subsequent VIP. This reduces the inrush currents in the system, which reduces the level of electromagnetic interference.7.3.p. f-ly7il

The invention relates to electrical engineering and can be used as a power supply system for a complex of radio electronic equipment (REA).

The purpose of the invention is to improve the weight and size characteristics, increase reliability by reducing electromagnetic interference, as well as simplify the system.

FIG. 1 is a general block diagram of a power supply system for N loads; in fig. 2 shows a partial block diagram of a system with secondary power sources of various types, as well as various types of current sensors; FIG. 3 and 4 - variants of the system with matching nodes in the form of a software logic node {in FIG. 5-7 are variants of power supply systems in which the matching node is simplified by using only the output, voltage of the secondary power source supplied to one of the inputs of the control node of the secondary power source of the next power on (the secondary power sources of the preliminary power must be stabilized).

The power supply system N loads (Fig. 1) contains a primary AC network 1 (PS), connected to it is a primary voltage converter 2 constant voltage. (PTPN), the output of which is connected to the inputs of the secondary power sources 3-6 (VIP, -VIP), connected by outputs with functional loads 7-10 (FN,), each VIP. 4-6 (VIP; -VINf) the subsequent inclusion contains in the input power

bus regulating element 11 (), the control input of which is connected to the output of the control unit 12 (), made

with at least one input, the output filtering unit 13 (VFU-VFU) connected between the input power bus and the output (,), and each . This pre-switching VIP (VIP, -VIP,) contains output 14 (.- ,,) of current sensor 15 (.) in the power bus. New system communications are formed with the help of the entered matching nodes 16–18 (US,. – US) connecting the VIPTs in series, with the US output connected to the input of the control unit in the subsequent switching VIP, and the US input connected to the current sensor VC: at the VIP pre-switch.

FIG. 2 is a partially disclosed block diagram of a power supply system with various types of TTI — linear voltage regulator 3 (VIP);

unstabilized voltage converter L (TLI), pulse voltage regulator 5 (TFd). At the same time in FIG. 2 given various types of current sensors - a resistor-transistor current sensor in the VIP,

the output terminal of the unstabilized converter used simultaneously as a current sensor in the VIPd,

inductive transistor current sensor in VIP.

The proposed power supply system (Fig. 1 and 2) works as follows.

. When the primary AC mains is turned on, a voltage appears at the input of the PSDN, the output voltage of which (+ UN) is simultaneously applied to the inputs,. However, after connecting +1} the power-up occurs sequentially in time. While some pre-switching VIP is turned off, the subsequent switching-on VIP is also turned off due to the fact that the control node is 12 VIP, 1 is fed from the code of the matching USB node the control signal from VK 14 DT 15 VIP ;. the driving regulating element 11 in the TTI, in the closed state, while from the PPSP consumes only current BHII.j and the TIP prior to it being turned on. . The VIP is switched on either directly by the voltage + Uf (Fig. 1), or by means of an external control signal (Fig. 2), after which the transient process starts in the VIP, and the current levels in both the input and output power bus functionally interconnected and significantly exceed their steady-state value, that DT 15 is recorded when it is turned on to any of the power tires. The signal on VC 14 VIP continues to affect the CS, so that the latter maintains the VIP in the off state and, therefore, all the subsequent VIPs are turned off. After setting the current in the power pin to some value specified in advance by the DT 15, the signal on the VC 1 via the AC) acts on the VU 12 VIP, opening the ER 11 in it and thereby turning on the VIP. Similarly to the above, further interaction occurs over the DT-BKj-yC + RE circuit; | (for each pair of sources. And the entire system is turned on, if the PITP is stabilized at the output voltage and equipped with a current protection device having an Ipep threshold its nominal current exceeding 1cotum, then its installed power, which determines its size, is related to its rated power Pd and the parameters of the system’s VIP with the following ratios l KjHOMi 1M 2; where flt is the power factor. - output voltage and nomiC Nominal current load current of the 1st source, is the efficiency of the i-ro source. . From expression (1) it is obvious that the construction of the power supply system should approximate vol. to one, which is decided by the alternate inclusion of the VIP. At the same time, the maximum input current for the i-ro TTI of the subsequent switching on (IftxMasc must satisfy the following inequality: 1 r - ik IH HoMk csr-n I: 2, 3, ..., N 1, /, 1- | and input voltage TIP (PITP output voltage). If pulsed voltage regulators (VPSs) are used, an oscillatory process occurs in the output filter at the time the regulating element is removed, which leads to a significant increase in the input current. The latter can be expressed from the theory of oscillations (assuming that input filter in the stabilizer-absent) in the form (IBK МО.КС) i с-Р- sin arccos (1-У,) г -, (3) о J h;; ТГ Р ° 1 t coefficient Uj V cf transfer agentJ impedance, inductance and output filter capacity i -ro After converting the trigonometric function in (3), we obtain VHO. -uf-yi- () The rise time of the voltage to the nominal value and the current to the maximum is determined from the simulated) Estimates show that for real circuits the value (ah ... J {3-4 times the IKHO “A magnitude of tg. are fractions of milliseconds.

The time constant in the control circuit in the case of stabilized sources is usually much less, therefore in such sources the output voltage transient is established faster than the current transient, since the current decay time from the maximum value of one order with tg, -.

The minimization of the on-time of the entire system is achieved if the signal received from the VC of the current sensor fully reflects the transient process of the VC current with a minimum delay and causes a signal proportional to the level of overcurrent. For this case, there are variants of the system (Figs. 3 and 4) with the execution of a CSS as a program logic node (PrU) 16 and 17, processing the signal from BC 14, and issuing a signal to CU 12. Pulse stabilizers are used as SPTA 1 and 2 voltage with DT 15, similar to DT shown in Fig.2. Due to the nonlinearity of the characteristic of the output transistor in the DT, the signal on the VC is close to proportional in the binary code depending on the level of the current excess and during the process of setting the current changes into a sequence of 0,1,0 codes. This sequence of logical information is fed to the Pru input, formed by the interconnected inputs of inverter 19 and RSD flip-flop 20, the outputs of which are connected to the inputs of the Schaeffer element 21, the output of which forms the output of the DG. As a result, at outputs 19 and 20, we have the sequences Kodo 1.0.1 and 0.1.1, respectively, and at output 21 and, therefore, at the output of Pr1, 1.0. The prU outputs, at the output, O, including the VU and, respectively, the OM, only after the occurrence and then disappearance of the current level in the power circuit of the VIP 1, i.e. only after the establishment of the transition process.

Depending on the execution of the VU, the information required at its output may be in the form of both direct (0, 0, 1) and inverted (1, 1, 0) code sequence. Thus, in the general form, the PRA should solve the problem of converting the sequence x, x, x to the sequence y, y, y; . where xefOI, yCfOl.

FIG. 4 shows a variant of the system with simplification (as compared with the system in FIG. 3) of the PRA. The latter is achieved through the introduction of additional links to the outputs of the VIP. PrU 16 and 17 are made in this case with two inputs and transform a sequence of logical information of the form x, x, x on the first input and x, x, x on the second input to the output sequence y, y, y where ,, ye {0i | , while the first input I of the control panel is connected to VK 14 DT 15, and the second input II is connected to the output of the pre-switching VIP: PrU 16 - to the VIP)), PrU 17 to the VIP ,; . Typical PrU variants are made on an optoelectronic intertor 19 whose input forms the first PrU input, the output is connected to one of the inputs of the Scheffer .21 element (PrU 16) or the conjunctor 22 (PrU 17 whose output forms the PrU output, and the other input forms the second PrU input.

Thus, the operation of the PRD is controlled by signals proportional to the current and voltage of the pre-switching VIP. Depending on the state of VIP | the operation of the PRA and the VIP is carried out according to the logical scheme presented in the table.

In accordance with the table, the operation of the system in FIG. 4 occurs as follows.

When the VIP is turned off, there is no current in its circuit, O is supplied to the first input, the diodes of the optoelectronic inverter 19 are closed and the input of the Schaeffer element 21 is output from the output 19 1, and to the second input it comes from the output of the VIP | O, 16 we have a signal 1, closing RE VIP.

When the VIP starts turning on and the current in its power circuit becomes higher than the set value, the DT 15 transistor will open, both inverter 19 diodes will open and the inputs of the Schaeffer element 21 will receive a signal O from output 19 and still from input II of the control panel, while The output of the PRA is still the signal 1, which continues to maintain the RE VIP in the closed state.

When the voltage at the output of the VIP reaches the nominal value of Bych at the input II of the Pru will arrive sigI

But when the current transient has not been established, the signal O remains at the output 19, the PRA - 1 output and the PE BHOj remains in the closed state. Only after a current is established in the power circuit of the GNP |, the transistor DT 15 is again closed, the inverter 19 returns to its original state, having outputted the signal 21 to the input 21, and O is formed at the output of the PRA 16, opening the ER 11 and thus turning on BHIlj.

In a similar way, other pairs of preliminary and subsequent switching on VIN interact with each other. In this case, a conjunctor (PrU 17) can be used as the output element of the PRU, and the output at the output will be a direct sequence of codes 0, 0, 1, controlling the corresponding OM.

Thus, the indicated system (Fig. 4.) can be implemented with a minimum, as well as the system in Fig. 3, the turn-on time, but with a much simpler PrU circuit.

In a number of cases, especially when connecting a large number of relatively low-power TTIs, it is advisable to simplify the matching node using only the output voltage of the TIP supplied to one of the inputs of the VU TIP for the signal of the end of the transient process. subsequent inclusion. In this case, the VIP pre-inclusion must be stabilized.

Variants of such systems are given in FIG. 5-7.

FIG. 5, the system contains stabilized VIP and VIP - 3 and 4 in the form of pulsed voltage regulators of different polarities, containing the control unit 12 from the voltage source 23 (ION) and the amplifying and modulating node 24 (ATC), one input of which is connected to the output of the VIP, and the other to the NLI, the matching node 25 is made in the form of a delay unit (KB), the input of which is connected to the output.

The output terminal DT in this case is formed by the code of the VIP, and its signal only partially reflects the level of overcurrent, since the establishment of a transient eg 985038

as shown above, the output of the stabilized VIP is faster than the establishment of a complete transient in the output 5 filtering unit 13, including the input current transient. This determines the need for a delay unit with a delay time not exceeding the installation time of the transient process in the VFU 13.

Thus, when the system is turned on at the VIP output (and the subsequent VIP is turned on, we have O and only the VIP is turned on. At the time of setting the nominal value Ug (j | j, B VID on UU VIP2, O is still applied as a result of the operation of the KB) and only From cf. to UU VIP, signal 1, 20 including VIPP will be assigned.

The performance of the KB can be based on digital or analog elements ..

FIG. 6 shows an example of performing a KB as an RC filter and at the same time simplifying the SU by eliminating the auxiliary input. The output of the BR 25 is connected to the input of ION 23 and VIG1 of the subsequent switching on. When the VIP pre-power is turned off, the power supply of the ion in the subsequent switching-on VIP is absent, the voltage on the ION 23 is also absent, and the SMD 24 causes the ER 11 in this VIP to be open.

35 condition.

The occurrence of a voltage at the input of an IP leads, with a delay determined by the RC filter, to the appearance of voltages at the input and output of the ION 23

40 in the VIP of the subsequent inclusion, and 24 brings the ER 11 in this VIP to the working state, producing the inclusion of the VIP.

 . This system is implemented with stabilized VIPs of one polarity.

In a system with a VIP of one polarity, when constructing it in such a way that the output

50 pre voltage VIP

switching on is higher than the output voltage of the ion in the VIP of the subsequent switching on, and the stability of the output voltage of the VIP of the subsequent switching on is not

55 higher than the stability of the pre-switching VIP, it is possible to simplify the SU using the output voltage of the pre-VIP

9

switching on (or dying it) as a reference voltage for a subsequent VIP switching.

This case is presented in FIG. 7, where Ugjjix, the TTI performs the functions of an ION for a TTI, while the TIP is connected to the input of the BR 25, and the output of the latter is used as the output of the ION for the TIP.

Claims (8)

1. A power supply system N. of loads containing a primary voltage converter, the input of which is connected to the terminals for connecting the primary AC network, and the output to the inputs of the N secondary power sources, the outputs of which are connected to the terminals for connecting the corresponding load, each secondary power source 98503 consists of a regulating element connected to the input power bus of the source and a control input connected to the output of the controlling node with at least one input, and an output filtering node connected between the output of the regulating element and output to connect the corresponding load, and each tsyy 10, a secondary pre-switch power supply device includes a current sensor in the power bus, characterized in that, in order to improve the mass-dimensional characteristics and increase reliability by reducing electromagnetic interference, (N - 1) matching nodes are inputted to it, and the input of each matching one the node is connected to the output of the current sensor in the secondary power source of the preliminary switching on, and the output of each matching node is connected to the input of the control node of the secondary power source of the subsequent switching on. 2. The system according to claim 1, characterized in that the current sensor is made with a binary-proportional dependence of the output signal 3Q from the level of excess current in the power bus, and the matching node is made in the form of a software logic node that converts a sequence of logical information of the form JC x, x, x in sequence view y, y, y, where xefoi, ye {0,1. 3. The system of PP. 1 and 2, characterized in that the current sensor is in the form of a resistor, d0 included in the input power bus and shunt transition emitter-base of the transistor, the collector of which is connected to the output of the current sensor, the input software logic , g node is connected to the connection point of the inputs of the entered inverter and the trigger RSD, whose outputs are connected to the inputs of the introduced Schaeffer element, the output connected to the output „Software logic node. 4. The system according to claim 1, is distinguished by the fact that the current sensor is made with a binary-proportional dependence of the input 55 signal from the level of the excess current in the power bus, and the matching node in the form of a two-input software logic node that converts eleven a set of sequences of logical information of the form x, x, x at the first input and x, zG, x at the second input into the sequence at the output y, y, y, gdehb (01, ..., the first input of the software logic node is connected to the output of the sensor current, and the second to the output of the secondary pre-supply power source. 5. The system of PP. 1 and 4, characterized in that the software logic node is configured on an optoelectronic inverter and a conjunctor, while the output of the conjunctor forms the output of the matching node, one of the inputs of the conjunctor is connected to the output of the optoelectronic inverter, the other input is connected to the output of the secondary source pre-power, and the output of the current sensor of said source is connected to the input of the opto-electronic inverter. 6. The system according to claim 1, characterized by the fact that the secondary power sources are stabilized, the control node in each. ABOUT Switched off Transitional process power on Included . . 198503 The house of them consists of a voltage source and a damping-modulating node connected by one of the inputs to the output, and the other 5 input to the voltage source, the matching node is connected by an input to the output of the secondary pre-energized power source and is in the form of a delay unit. time delay where Ogp is the time of setting the current transient in the filtering unit. 7. The system of PP. 1 and 5, about tl and J5 is sensitive to the fact that secondary The power supplies have the same polarity and the output of the delay unit is connected to the input of the source of the reference voltage of the secondary power source 20 of subsequent switching on. 8.System popp. 1, 6 and 7, characterized in that, for the purpose of simplification, as a source of secondary reference voltage 25 of the power supply source of the subsequent switching on, the output of the matching node of the secondary source is used. power pre-power. Switched off one ABOUT Transitional about 1 process power on Included shpv  hirzi - ± ij 0 |    ° i j WIHSP S in l l., 1 , Ng m