RU2349518C1 - Space vehicle power supply system simulation stand - Google Patents

Abstract

FIELD: space engineering.

SUBSTANCE: invention relates to testing equipment and can be used in designing space vehicle power supply systems. The proposed device incorporates load simulator, storage batteries, solar battery simulator, voltage stabilisation and automatic control complex comprising charge/discharge devices, voltage stabiliser and ACS, "plus" and "minus" busses, automatic control system with computer and lines of data exchange between ACS, load simulator and stand subsystems, auxiliary equipment, base and correcting circuits.

EFFECT: higher accuracy and reliability of power supply system simulation.

2 dwg

Description

The invention relates to testing equipment and can be used in the design and ground experimental testing of the power supply system (BOT) of the spacecraft (SC).

In space technology, among others, the task is to increase the active life of automatic spacecraft. In this case, there is a tendency to increase the average daily electric power required for the normal functioning of the onboard equipment (BA) of the spacecraft. Therefore, the creation of a reliable BOT with a large resource of work is an urgent task.

The main source of electrical energy on the spacecraft are electric generators based on photovoltaic converters (PECs) placed on a solar battery (BS). In the shadow areas of the spacecraft’s orbit, the onboard equipment is powered by storage batteries (AB), which are periodically charged by the current generated by the BS.

The need for uninterrupted power supply of the BA with electricity and maintaining a stabilized voltage necessitates the use of a complex of automation and voltage stabilization (CAS), which is a complex electrical and electronic equipment, in a power supply system.

Due to their specificity, the components of the SEP spacecraft are designed and manufactured by various enterprises, then delivered to the spacecraft manufacturer after carrying out autonomous and other types of tests. To confirm the operability and the specified technical characteristics, it is necessary to conduct comprehensive tests of the BOT before its regular operation. The technology for conducting complex tests of EPPs has its own characteristics and, as a rule, differs significantly from traditional methods based on the use of a standard device as an object of testing.

The simplest way to conduct complex tests of EPAs is to conduct ground-based electrical tests as part of a standard spacecraft. In this case, standard AB and CAS are used, and instead of a BS its electronic simulator is used. The load is on-board equipment that consumes electricity from both the solar battery simulator (IHD) and the battery, depending on the amount of current consumed. Comprehensive tests of SEPs of this type are part of the tests of the entire spacecraft (Kozlov D.I., Anshakov G.P. and others. Design of automatic spacecraft. - M.: Mechanical Engineering, 1996, 448 pp., 2 chap.).

A partial or complete limitation of the comprehensive tests of SEAs carried out autonomously outside a regular spacecraft is justified only if the SEA has passed flight design tests as part of other spacecraft and is not a new development. Otherwise (when conducting complex tests as part of a full-time spacecraft), if there are malfunctions, there may be large labor and financial costs associated with the dismantling (installation) of the SEP components already installed on board the spacecraft with their corresponding sending to the manufacturer for repair .

Thus, for newly designed BOTs, it becomes necessary to conduct comprehensive tests at special stands.

A well-known stand for modeling and testing the power supply system outside the full-time spacecraft (for example, designed according to the technical specifications 353EU46KS-651-1501 TZ-2, GNPRKTS "TsSKB-Progress", Samara, 2000), containing a load simulator (IN) BA , a control system (SU) with a computer, auxiliary equipment, including thermal management facilities (COTS), AB, IHD, CAS, consisting of charge-discharge devices (ZRU) and a voltage stabilizer and automation (SNA), " plus and minus tires connecting the UAN elements with a heat simulator narrow, AB and IHD with the formation of the subsystems "AB + ZRU" and "IHD + SNA" connected in parallel with the load simulator.

Figure 1 shows the device of the prototype. A well-known stand consists of a load simulator 1, batteries 2, a solar battery simulator 3, a complex of automation and voltage stabilization, containing charge-discharge devices 4 and a voltage stabilizer and automation 5, from the "plus" and "minus" buses 6 connecting the UAN elements with load simulator 1, AB 2 and IHD 3 with the formation of subsystems "AB + ZRU" and "IHD + SNA" connected in parallel with ID 1, from control system 7 with a computer and information communication lines (cables) between SU 7, IN 1 and subsystems ("AB + ZRU" and "CHD + SNA"), from auxiliary equipment, including means for providing the thermal regime of 8 elements of the stand (AB 2, KAS, etc.), as well as from the base 9, which serves to form the stand into an interconnected structure.

In the prototype, the objects of modeling (imitation) are a solar battery and on-board equipment consuming electrical energy from a solar cell.

Modeling and testing of the BOT using a well-known stand is as follows.

The planned sequence diagram of the change in the current consumed by the BA is fully reproduced by the load simulator (IN) 1. Depending on the value of the IN 1 current, the IHD current and the spacecraft operating mode (the number of “AB + ZRU” subsystems turned on, work in the light or shadow portion of the orbit) load simulator 1 can be powered only from AB 4, only from IHD 5 or simultaneously from AB 4 and IHD 5.

The operating modes of the stand are set by the control system 2.

Information on the BEP parameters generated in CAS, on the parameters of IHD 5 and ID 1 is output to the control system 2 computer. The solar battery simulator 5 operates in the current source mode, whose current-voltage characteristic differs significantly from the current-voltage characteristic of a standard BS.

The latter circumstance significantly reduces the accuracy of reproduction of individual characteristics of the components of the SES, and in some cases is the reason for the impossibility of modeling the operation of the SES as a whole.

The cost of the stand, in many respects, is determined by the cost of the used full-size batteries manufactured according to the standard documentation.

The task of correcting the current-voltage characteristics of IHD and bringing it closer to the current-voltage characteristics of a standard BS is technically solvable, however, the cost of the stand in this case will still increase significantly.

Thus, the disadvantage of the prototype is its high cost and relatively low simulation accuracy.

The objective of the invention is to increase the accuracy of modeling the BOT, as well as reducing the cost of manufacturing and operation of the stand.

This problem is solved by the fact that in the well-known stand for modeling and testing the SEP KA, which consists of a load simulator, batteries, a solar battery simulator, a complex of automation and voltage stabilization, containing charge-discharge devices and a voltage stabilizer and automation, from the "plus" and "negative" buses connecting the UAN elements with a load simulator, AB and IHD with the formation of the subsystems "AB + ZRU" and "IHD + SNA" connected in parallel with the IN from a control system with a computer and information lines of the communication between the SU, IN and the subsystems of the stand, from auxiliary equipment, including means to ensure the thermal regime of the components of the solar cells, as well as from the base, which serves to form the stand into an interconnected design, correction devices were introduced - a physical model of a solar battery and physical models of rechargeable batteries batteries made with scaling factors for current and voltage, which are connected to a common digital bus through the interface blocks, which serve to change their operating modes A high-speed information exchange with the control system and uniting parts of the stand in a logical and functionally coordinated circuit simulating the output and other characteristics of a real power supply system, and the storage batteries of the power supply system of the stand are made in the form of electronic simulators.

Figure 2 shows the device of the proposed stand for modeling the EPA KA.

The stand consists of a load simulator 1, rechargeable batteries 2, made in the form of electronic simulators, a solar battery simulator 3, a complex of automation and voltage stabilization, containing charge-discharge devices 4 and a voltage regulator and automation 5, from the "plus" and "minus" tires 6 connecting the UAN elements with a load simulator 1, AB 2 and IHD 3 with the formation of subsystems "AB + ZRU" and "IHD + SNA" connected in parallel with ID 1, from the control system 7 with a computer and information communication lines (cables) with ID 1 and subsystem Mom ("AB + ZRU" and "CHD + CHA"), from auxiliary equipment, including means for providing thermal conditions (COT) 8 elements of the stand, from corrective devices - the physical model of the solar battery (FM BS) 9, including a small battery photoelectric and illuminator of physical models of rechargeable batteries (FM AB) 10, from interface units (BLs) 11 and 12 of the physical model of solar battery 9 and physical models of rechargeable batteries 10, respectively, from a common digital bus 13, and also from the base (Main) 14 serving to form Tenda into a coherent structure.

In this stand, objects of modeling (imitation), in addition to the battery of solar and on-board equipment (as in the prototype), are also rechargeable batteries. In addition, correction devices were introduced - physical models of storage batteries 10 and physical model of solar battery 9, as well as interface units 11 and 12 of these correction devices with other equipment of the stand and digital bus 13.

The functioning of the stand in the process of modeling (and testing) BOT is as follows.

The physical model of the solar 9 battery is illuminated, its current-voltage characteristic is taken, which is scaled taking into account the given coefficients and state (operating mode) of the FM BS 9 and via digital bus 13, through the interface unit 11 and SU 7, it is transmitted for execution to the battery simulator solar 3. Information on the values of voltages, as well as capacities and temperatures of FM AB 10 from interface units 12 via digital bus 13 after scaling accordingly with a given coefficient, as well as conversion according to calibration characteristics given for installation in AB 2 (made in the form of electronic simulators). From the control system of the stand 7 in the load simulator 1 on the digital bus 13 sets the current values corresponding to the current consumption of the on-board equipment. After switching on switchgear 4 and SNA 5 of the automation and voltage stabilization complex, depending on the set voltage values on the AB 2 and the currents on the load simulator 1 and IHD 3, the charge or discharge currents of the batteries 2 are established. CAS, in turn, carries out auto-regulation of the consumed CHD 3 power by shifting the voltage of the operating point of the current-voltage characteristics of the latter. The measured values of the currents of the charge (or discharge) AB 2 and the voltage of the operating point of the IBS 3 via the digital bus 13 from the SU 7 are transmitted to the interface units 11 and 12, which change the operating modes of the physical model of the solar battery 9 and the physical models of the battery 10, respectively.

The simulation process is repeated in accordance with the changing cyclograms of illumination and load, as well as the conditions (operating modes) of FM BS 9.

Various CVCs for IHD 3, depending on the illumination and conditions (modes) of the BS operation, which it simulates, load cyclograms for ID 1, control of the BOT (CAS), data exchange between the elements of the stand through the digital bus 13 in accordance with the approved information protocol exchange, as well as recording the results of the work of the stand are implemented using a computer control system 7 means of special software.

Means of providing thermal conditions 8 provide the desired temperature of the elements of the stand: physical models of batteries 10, their matching units 12, switchgear 4, SNA 5 and, if necessary, others.

An increase in the accuracy of simulating the operation of the SEP spacecraft is achieved through the use of FM BS 9 and FM AB 10, since they practically monitor the current-voltage characteristics of BS and AB, respectively, used on a standard spacecraft.

The cost of the stand is reduced by replacing the standard batteries with their electronic simulators and large-scale physical models. The universal parts of the stand are used for modeling and testing the SEP of subsequent products, which speeds up the payback of this stand and reduces the cost of manufacturing the next.

Thus, the proposed stand for modeling the power supply system of the spacecraft allows to increase the accuracy of modeling and reduce the cost of manufacturing and operating the stands for the experimental development of the solar cells.

Claims (1)

A bench for modeling the power supply system of a spacecraft, containing a load simulator, rechargeable batteries, a solar battery simulator, a complex of automation and voltage stabilization, including charge-discharge devices and a voltage stabilizer and automation, plus and minus buses connecting the UAN elements with a simulator load, AB and IHD with the formation of the subsystems "AB + ZRU" and "IHD + SNA" connected in parallel with the IN, a control system with a computer and information communication lines between the SU, IN and the subsystem mi stand, auxiliary equipment, including means for ensuring the thermal regime of the components of the solar cells, as well as the base used to form the stand in an interconnected design, characterized in that the stand is equipped with corrective devices - a physical model of the solar battery and physical models of rechargeable batteries, made with scaling factors for current and voltage, which are connected to a common digital bus through the interface blocks that serve to change their operating modes high-speed information exchange with the control system and the uniting parts of the stand in a logically and functionally coordinated circuit that simulates the output and other characteristics of a real power supply system, and the storage batteries of the power supply system of the stand are made in the form of electronic simulators.

Images