Multilevel Voltage Space Vector Generation For Induction Motor Drives Using Conventional Two-Level Inverters And H-Bridge Cells

Siva Kumar, K

01 1900

Multilevel voltage source inverters have been receiving more and more attention from the industry and academia as a choice for high voltage and high power applications. The high voltage multilevel inverters can be constructed with existing low voltage semiconductor switches, which already have a mature technology for handling low voltages, thus improving the reliability of the overall inverter system. These multilevel inverters generate the output voltage in the form of multi-stepped waveform with smaller amplitude. This will result in less dv/dt at the motor inputs and electromagnetic interference (EMI) caused by switching is considerably less. Because of the multi-stepped waveform, the instantaneous error in the output voltage will be always less compared to the conventional two-level inverter output voltage. It will reduce the unwanted harmonic content in the output voltage, which will enable to switch the inverter at lower frequencies. Many interesting multi level inverter topologies are proposed by various research groups across the world from industry and academic institutions. But apart from the conventional 3-level NPC and H-bridge topology, others are not yet highly preferred for general high power drives applications. In this respect, two different five-level inverter topologies and one three-level inverter topology for high power induction motor drive applications are proposed in this work. Existing knowledge from published literature shows that, the three-level voltage space vector diagram can be generated for an open-end winding induction motor by feeding the motor phase windings with two two-level inverters from both sides. In such a configuration, each inverter is capable of assuming 8 switching states independent of the other. Therefore a total of 64 switching combinations are possible, whereas the conventional NPC inverter have 27 possible switching combinations. The main drawback for this configuration is that, it requires a harmonic filter or isolated voltage source to suppress the common mode currents through the motor phase winding. In general, the harmonic filters are not desirable because, it is expensive and bulky in nature. Some topologies have been presented, in the past, to suppress the common mode voltage on the motor phase windings when the both inverters are fed with a single voltage source. But these schemes under utilize the dc-link voltage or use the extra power circuit. The scheme presented in chapter-3 eliminates the requirement of harmonic filter or isolated voltage source to block the common mode current in the motor phase windings. Both the two-level inverters, in this scheme, are fed with the same voltage source with a magnitude of Vdc/2 where Vdc is the voltage magnitude requires for the NPC three-level inverter. In this scheme, the identical voltage profile winding coils (pole pair winding coils), in the four pole induction motor, are disconnected electrically and reconnected in two star groups. The isolated neutrals, provided by the two star groups, will not allow the triplen currents to flow in the motor phase windings. To apply identical fundamental voltage on disconnected pole pair winding, decoupled space vector PWM is used. This PWM technique eliminates the first center band harmonics thereby it will allow the inverters to operate at lower switching frequency. This scheme doesn’t require any additional power circuit to block the triplen currents and also it will not underutilize the dc-bus voltage. A five-level inverter topology for four pole induction motor is presented in chapter-3. In this topology, the disconnected pole pair winding coils are effectively utilized to generate a five-level voltage space vector diagram for a four pole induction motor. The disconnected pole pair winding coils are fed from both sides with conventional two-level inverters. Thereby the problems like capacitor voltage balancing issues are completely eliminated. Three isolated voltage sources, with a voltage magnitude of Vdc/4, are used to block the triplen current in the motor phase windings. This scheme is also capable of generating 61 space vector locations similar to conventional NPC five-level inverter. However, this scheme has 1000 switching combinations to realize 61 space vector locations whereas the NPC five-level inverter has 125 switching combinations. In case of any switch failure, using the switching state redundancy, the proposed topology can be operated as a three-level inverter in lower modulation index. But this topology requires six additional bi-directional switches with a maximum voltage blocking capacity of Vdc/8. However, it doesn’t require any complicated control algorithm to generate the gating pulses for bidirectional switches. The above presented two schemes don’t require any special design modification for the induction machine. Although the schemes are presented for four pole induction motor, this technique can be easily extend to the induction motor with more than four poles and thereby the number of voltage levels on the phase winding can be further increased. An alternate five-level inverter topology for an open-end winding induction motor is presented in chapter-4. This topology doesn’t require to disconnect the pole pair winding coils like in the previous propositions. The open-end winding induction motor is fed from one end with a two-level inverter in series with a capacitor fed H-bridge cell, while the other end is connected to a conventional two-level inverter to get a five voltage levels on the motor phase windings. This scheme is also capable of generating a voltage space vector diagram identical to that of a conventional five-level inverter. A total of 2744 switching combinations are possible to generate the 61 space vector locations. With such huge number switching state redundancies, it is possible to balance the H-bridge capacitor voltage for full modulation range. In addition to that, the proposed topology eliminates eighteen clamping diode having different voltage ratings compared to the NPC inverter. The proposed topology can be operated as a three-level inverter for full modulation range, in case of any switch failure in the capacitor fed H-bridge cell. All the proposed topologies are experimentally verified on a 5 h.p. four pole induction motor using V/f control. The PWM signals for the inverters are generated using the TMS320F2812 and GAL22V10B/SPARTAN XC3S200 FPGA platforms. Though the proposed inverter topologies are suggested for high-voltage and high-power industrial IM drive applications, due to laboratory constraints the experimental results are taken on the 5h.p prototypes. But all the proposed schemes are general in nature and can be easily implemented for high-voltage high-power drive applications with appropriate device ratings.

Induction Motors

Inverters

H-Bridge Cells

Multilevel Voltage Source Inverters

Induction Motor Drives

Winding Induction Motor

Multi-Level Inverters

Multilevel Inverter Topologies

Induction Motor Drive

Heat Engineering

Investigations On Sensorless Vector Control Using Current Error Space Phasor And Direct Torque Control Of Induction Motor Drive Based On Hexagonal And 12-Sided Polygonal Voltage Space Vectors

Ramubhai, Patel Chintanbhai

02 1900

Variable-speed Induction motor drives are nowadays used for various kinds of industrial processes, transportation systems, wind turbines and household appliances in the world. The majority of drives are for general purpose speed control applications where accurate speed control is not required for entire speed range. But for high dynamic drive application, very precise and fast control of induction motor drive is essential. For such applications, sophisticated and well-performing control design is a key issue. Precise and accurate torque control of the Induction Motor (IM) can only be accomplished by vector control and direct torque control. In terms of space vector theory, vector control implies that the instantaneous torque is controlled by way of the stator current vector that is orthogonal to the rotor flux vector. Precise knowledge of the rotor flux angle is therefore essential for a vector controlled IM. IMs do not allow the flux position to be easily measured, so most modern vector controlled IM drives rely on flux estimation. This means that the flux angle is derived from a flux estimator, using the dynamic model of the IM. Given that the rotor speed of the IM is measured by a mechanical shaft sensor. Flux estimation is a fairly easy task. However, vector control of IM without mechanical shaft speed sensor is of current interest in industrial environment. The driving motivations behind the development in sensorless control are lower cost, improved reliability and operating environment. In this thesis, a sensorless vector control scheme for rotor flux estimation using current error space phasor based hysteresis controller is proposed including the method for estimation of leakage inductance, Ls. For frequencies of operation less than 25 Hz, the rotor voltage and hence the rotor flux position is computed during the inverter zero voltage space vector using steady state model of IM. For above 25 Hz, active vector period and steady state model of IM is used. The whole rotor flux estimation scheme is dependent on current error space phasor and the steady state motor model, with rotor flux as a reference vector. Since no terminal voltage sensing is involved, dead time effects will not create problem in rotor flux sensing at low frequencies of operation. But appropriate device on-state drop are compensated at low frequencies (below 5 Hz) of operation to achieve a steady state operation up to less than 1 Hz. A constant switching frequency hysteresis current controller is used in inner current control loop for the PWM regulation, with smooth transition of operation to six-step mode operation. A simple Ls estimation based on current error space phasor is also proposed to nullify the deteriorating effect on rotor flux estimation. The parameter sensitivity of the control scheme to changes in the stator resistance Rs is also investigated. The drive scheme is tested up to a low frequency operation less than 1 Hz. The extensive simulation and experiment results are presented to show the proposed scheme’s good dynamic performance extending up to six-step operation. In contrast to vector control, direct torque control (DTC) method requires the knowledge of stator resistance only and thereby decreasing the associated sensitivity to parameters variation and the elimination of speed information. DTC as compared to vector control does not require co-ordinate transformation and PI controller. DTC is easy to implement because it needs only two hysteresis comparators and a lookup table for both flux and torque control. This thesis also investigates the possibilities in improvement of direct torque control scheme for high performance induction motor drive applications. Here, two schemes are proposed based on the direct torque control scheme for IM drive using 12-sided polygonal voltage space vectors for fast torque control. The torque control scheme based on DTC algorithm is proposed using 12-sided polygonal voltage space vector. The basic DTC scheme is used to control the torque. But the IM drive is open-end type. For torque control, the voltage space vectors orthogonal to stator flux vector in 12-sided polygonal space vector structure are used as hexagonal space vector based DTC scheme. The advantages achieved due to 12-sided polygonal space vector are mainly fast torque control and small torque ripple. The fast transient of torque with precise control is achieved using voltage space vector placed with a resolution of ±15. The torque ripple will be less as 6n±1 (n=odd) harmonic torque is totally eliminated from the whole range of PWM modulation. The comparative analysis of proposed 12-sided polygonal voltage space vector based DTC and conventional hexagonal space vector based DTC is also presented. Extensive simulation and experiment results are also presented to show the fast torque control at speeds of operation ranging from 5 Hz to the rated speed. The concept of 12-sided polygonal space vector based DTC is further extended for a variable speed control scheme using estimated fundamental stator voltage for sector identification. The conventional DTC scheme uses stator flux vector for identification of the sector and the switching vector are selected based on this sector information to control stator flux and torque. However, the proposed DTC scheme selects switching vectors based on the sector information of the estimated fundamental stator voltage vector and its relative position with respect to the stator flux vector. The fundamental stator voltage estimation is based on the steady state model of IM and information of synchronous frequency which is derived from computed stator flux using a low pass filter technique. The proposed DTC scheme utilizes the exact position of fundamental stator voltage vector and stator flux vector position to select optimal switching vector for fast control of torque with small variation of stator flux within hysteresis band. The present DTC scheme allows the full load torque control with fast transient response to very low speeds of operation below 5 Hz. The extensive simulation and experiment results are presented to show the fast torque control for speed of operation from zero speed to rated speed. However, the present scheme will have all the advantages of DTC scheme using stator flux vector for sector identification. All the above propositions are first simulated by MATLAB/Simulink and subsequently verified by an experimental laboratory prototype. The proposed control schemes are experimentally verified on a 3.7 kW IM drive. The control algorithms of the sensorless vector control using current error space phasor as well as DTC using 12-sided polygonal voltage space vector are completely implemented on a TI TMS320LF2812 DSP controller platform. These are some of the constituents for chapters 2, 3 and 4 in this thesis. Additionally, the first chapter also covers a brief survey on some of the recent progresses made in the field of sensorless vector control, direct torque control and current hysteresis controller. The thesis concludes with suggestion for further exploration.

Induction Motor Drives

Sensorless Vector Control

Direct Torque Control (DTC)

Voltage Space Vectors

Hysteresis Controller

12-sided Polygonal Voltage Space Vectors

IM Drive

Hexagonal Space Vector

Heat Engineering

Space-Vector-Based Pulse Width Modulation Strategies To Reduce Pulsating Torque In Induction Motor Drives

Hari, V S S Pavan Kumar

07 1900

Voltage source inverter (VSI) is used to control the speed of an induction motor by applying AC voltage of variable amplitude and frequency. The semiconductor switches in a VSI are turned on and off in an appropriate fashion to vary the output voltage of the VSI. Various pulse width modulation (PWM) methods are available to generate the gating signals for the switches. The process of PWM ensures proper fundamental voltage, but introduces harmonics at the output of the VSI. Ripple in the developed torque of the induction motor, also known as pulsating torque, is a prominent consequence of the harmonic content. The harmonic voltages, impressed by the VSI on the motor, differ from one PWM method to another. Space-vector-based approach to PWM facilitates a large number of switching patterns or switching sequences to operate the switches in a VSI. The switching sequences can be classified as conventional, bus-clamping and advanced bus-clamping sequences. The conventional sequence switches each phase once in a half-carrier cycle or sub-cycle, as in case of sine-triangle PWM, third harmonic injection PWM and conventional space vector PWM (CSVPWM). The bus-clamping sequences clamp a phase to one of the DC terminals of the VSI in certain regions of the fundamental cycle; these are employed by discontinuous PWM (DPWM) methods. Popular DPWM methods include 30 degree clamp PWM, wherein a phase is clamped during the middle 30 degree duration of each quarter cycle, and 60 degree clamp PWM which clamps a phase in the middle 60 degree duration of each half cycle. Advanced bus-clamping PWM (ABCPWM) involves switching sequences that switch a phase twice in a sub-cycle besides clamping another phase. Unlike CSVPWM and BCPWM, the PWM waveforms corresponding to ABCPWM methods cannot be generated by comparison of three modulating signals against a common carrier. The process of modulation in ABCPWM is analyzed from a per-phase perspective, and a computationally efficient methodology to realize the sequences is derived. This methodology simplifies simulation and digital implementation of ABCPWM techniques. Further, a quick-simulation tool is developed to simulate motor drives, operated with a wide range of PWM methods. This tool is used for validation of various analytical results before experimental investigations. The switching sequences differ in terms of the harmonic voltages applied on the machine. The harmonic currents and, in turn, the torque ripple are different for different switching sequences. Analytical expression for the instantaneous torque ripple is derived for the various switching sequences. These analytical expressions are used to predict the torque ripple, corresponding to different switching sequences, at various operating conditions. These are verified through numerical simulations and experiments. Further, the spectral properties are studied for the torque ripple waveforms, pertaining to conventional space vector PWM (CSVPWM), 30 degree clamp PWM, 60 degree clamp PWM and ABCPWM methods. Based on analytical, simulation and experimental results, the magnitude of the dominant torque harmonic with an ABCPWM method is shown to be significantly lower than that with CSVPWM. Also, this ABCPWM method results in lower RMS torque ripple than the BCPWM methods at any speed and CSVPWM at high speeds of the motor. Design of hybrid PWM methods to reduce the RMS torque ripple is described. A hybrid PWM method to reduce the RMS torque ripple is proposed. The proposed method results in a dominant torque harmonic of magnitude lower than those due to CSVPWM and ABCPWM. The peak-to-peak torque in each sub-cycle is analyzed for different switching sequences. Another hybrid PWM is proposed to reduce the peak-to-peak torque ripple in each sub-cycle. Both the proposed hybrid PWM methods reduce the torque ripple, without increasing the total harmonic distortion (THD) in line current, compared to CSVPWM. CSVPWM divides the zero vector time equally between the two zero states of a VSI. The zero vector time can optimally be divided to minimize the RMS torque ripple in each sub-cycle. It is shown that such an optimal division of zero vector time is the same as addition of third harmonic of magnitude 0.25 times the fundamental magnitude to the three-phase sinusoidal modulating signals. ABCPWM applies an active state twice in a sub-cycle, with the active vector time divided equally. Optimal division of active vector time in ABCPWM to minimize the RMS torque ripple is evaluated, both theoretically and experimentally. Compared to CSVPWM, this optimal PWM is shown to reduce the RMS torque ripple significantly over a wide range of speed. The various PWM schemes are implemented on ALTERA CycloneII field programmable gate array (FPGA)-based digital control platform along with sensorless vector control and torque estimation algorithms. The controller generates the gating signals for a 10kVA IGBT-based two-level VSI connected to a 5hp, 400V, 4-pole, 50Hz squirrel-cage induction motor. The induction motor is coupled to a 230V, 3kW separately-excited DC generator.

Pulse Width Modulation

Space Vector

Pulsating Torque

Torque Ripple

Induction Motor Drives

Space Vector PWM

Current Ripple

Voltage Source Inverter (VSI)

Electrical Engineering

Impasses do segundo dualismo pulsional freudiano

Campos, Ana Paula Soares

10 February 2015

Submitted by Renata Lopes (renatasil82@gmail.com) on 2016-01-07T12:17:37Z No. of bitstreams: 1 anapaulasoarescampos.pdf: 496075 bytes, checksum: d5d3679c1f15801b7d782cd17fb7eb68 (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2016-01-25T16:42:35Z (GMT) No. of bitstreams: 1 anapaulasoarescampos.pdf: 496075 bytes, checksum: d5d3679c1f15801b7d782cd17fb7eb68 (MD5) / Made available in DSpace on 2016-01-25T16:42:35Z (GMT). No. of bitstreams: 1 anapaulasoarescampos.pdf: 496075 bytes, checksum: d5d3679c1f15801b7d782cd17fb7eb68 (MD5) Previous issue date: 2015-02-10 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Com a impossibilidade de sustentar o primeiro dualismo, Freud se viu diante da ameaça de ter que admitir um monismo pulsional. No entanto, Freud sempre considerou fundamental pressupor um dualismo. Em Além do princípio do prazer (1920), ao refletir sobre a relação entre a compulsão à repetição e a atividade pulsional, ele chega ao conceito de pulsão de morte. Em oposição a esta nova classe de pulsão, Freud apresenta a pulsão de vida e, assim, substitui o primeiro dualismo pulsional. Ambas as classes de pulsões teriam entrado em ação com o surgimento da vida a partir da matéria inorgânica. Enquanto a pulsão de morte buscaria retornar ao estado inorgânico, a pulsão de vida buscaria complexificar a vida, dificultando a morte do organismo. Mas a hipótese do segundo dualismo apresenta uma série de dificuldades, que colocam em questão até que ponto Freud conseguiu sustentá-la. Ele próprio reconhece, na obra de 1920, que o novo dualismo pulsional não apresenta o mesmo grau de certeza que os passos anteriores do desenvolvimento de sua teoria das pulsões. O objetivo deste trabalho é, em primeiro lugar, analisar a teoria apresentada em Além do princípio do prazer e discutir alguns dos principais problemas presentes na argumentação freudiana. Em seguida, procuramos analisar as hipóteses elaboradas por Freud sobre as duas classes de pulsões em textos posteriores, tendo em vista analisar em que medida ele consegue sustentar a primariedade e a independência das duas classes de pulsões no restante de sua teoria. Concluímos que os impasses presente no texto de 1920 não são plenamente solucionados e procuramos apontar as principais questões que permanecem em aberto na teoria freudiana acerca do segundo dualismo pulsional. / With the impossibility of sustaining the first dualism, Freud was faced with the threat of having to admit a drive monism. However, Freud always considered fundamental to assume a dualism. In Beyond the Pleasure Principle (1920), when reflecting on the relationship between the repetition compulsion and drive activity, he gets the concept of the death drive. In opposition to this new drive class, Freud presents the life drive and, thus, replaces the first drive dualism. Both drive classes would act with the emergence of life from inorganic matter. While the death drive would return to the inorganic state, the life drive would make the life more complex, making the death of the organism harder. However, the second dualism hypothesis presents a number of difficulties which begs the question if Freud was able to sustain this. In his work of 1920, he recognizes that the new drive dualism does not present the same degree of certainty that the previous steps of the development of his theory of drives. The objective here is, first, to analyze the theory presented in Beyond the Pleasure Principle and discuss some of the main problems present in Freud's argument. Then we analyzed the hypotheses developed by Freud regarding the two drive classes in later works in order to analyze how he can sustain the primarity and independence of the two drive classes in the remaining of his theory. We conclude that the impasses in the text of 1920 are not fully solved and we try to point out the main issues that remain open in the Freudian theory about the second drive dualism.

CNPQ::CIENCIAS HUMANAS::PSICOLOGIA

Psicanálise

Freud

Teoria das pulsões

Pulsão de vida

Pulsão de morte

Psychoanalysis

Freud

Theory of drives

Life drive

Death drive

Elektrisch-hydrostatische Kompaktantriebe mit Differentialzylinder für die industrielle Anwendung

Michel, Sebastian

13 October 2021

Elektrisch-hydrostatische Kompaktantriebe (EKA) stellen ein innovatives, neuar-tiges Antriebskonzept dar, welches – ausgeführt als funktionsfertige Baugruppe – die Anwenderfreundlichkeit bei der Maschinenintegration, Inbetriebnahme und Wartung signifikant steigert. Elektrisch-hydrostatische Kompaktantriebe verbinden die inhärenten Vorteile hydraulischer Antriebstechnik wie beispiels-weise Robustheit, hohe Leistungsdichte und Überlastschutz mit Energieeffizi-enz, Ressourceneffizienz, Anwenderfreundlichkeit und geringem Bauraum. Auf-grund seines kompakten und kostengünstigen Aufbaus ist der Differentialzylin-der der mit Abstand am häufigsten eingesetzte Aktor bei hydraulischen Anwen-dungen. Die Herausforderung beim Einsatz eines Differentialzylinders im hyd-rostatischen Getriebe ist die Steuerung der asymmetrischen Volumenströme, die durch die einseitige Kolbenstange hervorgerufen werden. Die vorliegende Arbeit widmet sich der systematischen Entwicklung und Unter-suchung von Schaltungskonzepten, die sich für elektrisch-hydrostatische Kom-paktantriebe mit Differentialzylinder für die industrielle Anwendung eignen. Vor dem Hintergrund eines ressourcenschonenden und wirtschaftlichen Einsatzes der Antriebe werden Vorzugsvarianten ermittelt, die sowohl energie- als auch kosteneffizient sind. Das statische und dynamische Übertragungsverhalten so-wie die Energieeffizienz der ausgewählten Schaltungen werden auf der Grund-lage von praxisnahen Demonstratoren bestimmt. Die analytische und experi-mentelle Untersuchung der Vorzugsvarianten zeigt das Potential und die Gren-zen der Schaltungskonzepte für den industriellen Einsatz auf. Darüber hinaus wird der Vergleich mit elektromechanischen Kompaktantrieben im gleichen Leistungsbereich geführt, um die erzielten Ergebnisse in der Gegenüberstellung einordnen zu können. Um die Notwendigkeit einer aktiven Kühlung für potentielle Einsatzgebiete ohne aufwendige Experimente abschätzen zu können, werden zudem die Methoden der thermo-energetischen Netzwerksimulation auf elektrisch-hydrostatische Kompaktantriebe angewendet. Anhand eines Beispielantriebs wird ermittelt, mit welcher Genauigkeit das thermo-energetische Verhalten und die sich einstel-lende Beharrungstemperatur berechnet werden können.:1 Einleitung 1 2 Zielstellung der Arbeit 6 3 Stand der Forschung 8 3.1 Grundlagen 8 3.2 Hydrostatische Getriebe mit Gleichgangzylinder 10 3.2.1 Elektrisch-hydrostatische Aktuatoren (EHA) 11 3.3 Hydrostatische Getriebe mit Differentialzylinder 13 3.4 Thermo-energetische Analyse und Modellierung 24 4 Systematisierung der Schaltungsmöglichkeiten 27 4.1 Analyse typischer Anwendungen für EKA 27 4.2 Systematisierung der Lastfälle 27 4.3 Schaltungssystematik 29 4.4 Auswahl von Vorzugsvarianten 35 5 Einpumpenkonzept mit Ausgleichsventil 40 5.1 Aufbau und Funktionsweise 40 5.2 Demonstrator 43 5.3 Statisches Betriebsverhalten 46 5.4 Dynamisches Übertragungsverhalten 47 5.4.1 Dynamische Streckenkennwerte 47 5.4.2 Lastfallspezifisches dynamisches Verhalten 57 5.4.3 Dynamisches Verhalten bei dominanten Massekräften 60 5.5 Energieeffizienz 89 5.5.1 Elektrischer Antrieb 91 5.5.2 Hydrostatisches Getriebe 93 5.5.3 Gesamtantrieb 96 5.6 Fazit und Einsatzempfehlungen 97 6 Tandempumpenkonzept im offenen Kreis 99 6.1 Aufbau und Funktionsweise 99 6.2 Demonstrator 101 6.3 Statisches Übertragungsverhalten 102 6.4 Dynamisches Übertragungsverhalten 103 6.4.1 Dynamische Streckenkennwerte 103 6.4.2 Lastfallspezifisches dynamisches Verhalten 106 6.5 Energieeffizienz 109 6.5.1 Hydrostatisches Getriebe 109 6.5.2 Gesamtantrieb 111 6.6 Fazit und Einsatzempfehlungen 112 7 Untersuchung eines elektromechanischen Referenzantriebs 114 7.1 Bauarten, Eigenschaften und Einsatzgebiete elektromechanischer Linearantriebe 114 7.1.1 Übersetzung 117 7.1.2 Maximale Hubgeschwindigkeit 117 7.1.3 Maximale Hubkraft 117 7.1.4 Lebensdauer und Verschleiß 118 7.1.5 Wirkungsgrad 120 7.1.6 Steifigkeit 120 7.1.7 Fail-safe 121 7.2 Referenzantrieb 121 7.3 Statisches Übertragungsverhalten 122 7.4 Dynamisches Übertragungsverhalten 122 7.5 Energieeffizienz 123 7.5.1 Kugelgewindetrieb 123 7.5.2 Gesamtantrieb 124 8 Vergleich und Bewertung der Antriebssysteme 126 8.1 Statisches Übertragungsverhalten 126 8.2 Dynamisches Übertragungsverhalten 127 8.3 Energieeffizienz 128 8.4 Weiterführender Vergleich und Bewertung 129 9 Thermo-hydraulische Netzwerksimulation 134 9.1 Methodik 134 9.2 Grundlagen der Thermodynamik und Wärmeübertragung 135 9.2.1 Wärmeleitung 136 9.2.2 Konvektion 136 9.2.3 Wärmestrahlung 138 9.2.4 Wärmeübergang an Fugen zwischen Bauteilen 139 9.3 Analyse der Verlustleistungen 142 9.4 Analyse der Wärmeströme und thermischen Widerstände 145 9.4.1 Erzwungene Konvektion zwischen Öl und Innenfläche 146 9.4.2 Wärmeleitung in Festkörpern (Gehäuse) 147 9.4.3 Wärmeübergang an Fugen zwischen Bauteilen 147 9.4.4 Freie Konvektion an den Außenflächen 148 9.4.5 Wärmestrahlung an den Außenflächen 150 9.4.6 Zusammenfassung 151 9.5 Zulässige Öltemperatur des Antriebs 152 9.6 Thermo-hydraulisches Simulationsmodell des Demonstrators 152 9.7 Validierung 155 9.7.1 Vorbetrachtungen an einer Modellgeometrie 155 9.7.2 Prüfstandsaufbau und Versuchsparameter 157 9.7.3 Gegenüberstellung von Simulation und Messung 159 9.8 Sensitivitätsanalyse 162 9.8.1 Variation der Verlustleistung 163 9.8.2 Variation der Umgebungstemperatur 164 9.8.3 Variation des Korrekturfaktors für Umgebungsströmungen 165 9.9 Simulationsstudie zur Verbesserung des Wärmeabgabevermögens 166 9.10 Zusammenfassung 166 10 Zusammenfassung und Ausblick 168 11 Literaturverzeichnis 172 12 Anhang 194

info:eu-repo/classification/ddc/620

ddc:620

Airgap-less Electric Motor

Maryam Alibeik (11173290)

06 August 2021

This dissertation focuses mainly on the airgap-less electric machine. An extensive literature review has been presented along with a systematic study that included analytical modeling, simulation with both steady-state and trasient analysis, prototype building, and experimental validation. In this type of device, the rotor is allowed to touch the stator at a contact point, which maximizes the internal flux and therefore the electromagnetic torque. A higher torque density motor is proposed in this dissertation due to a reduced reluctance caused by zero airgap situation. A comparison with other high torque density electric ma-chines demonstrates the advantages of the proposed machine. Switched reluctance motor for hybrid vehicle, integrated magnetic gear, induction machines, are some examples of the machines with lower torque density than the airgap-less electric machine. This machine will maximize the generated torque allowing these type of machines to be competitive in applications where hydraulic motors are prevalent, i.e., low-speed and high-torque requirements. Hydraulic motor systems face two major problems with their braking system and with low efficiency due to a large number of energy conversion stages (i.e., motor-pump, hydraulic connections and the hydraulic motor itself). The proposed electric motor, unlike hydraulic motors, converts electrical energy directly to mechanical energy with no extra braking system necessary and with higher efficiency. The evolution of the airgap-less electric machine from three poles to 9 bi-poles is discussed in this dissertation. The modeling of this machine with a minimum number of poles is discussed before a generalization is presented. The simulation and analysis of the airgap-less electric motor has been done using Euler integration method as well as Runge Kutta 4th order integration method due to its higher precision. A proof-of-concept electric machine with nine magnetic bipoles is built to validate the theoretical assumptions.

electrical engineering

power electronics

controls

airgap-less

rolling rotor

drives

state of the art

gap

airgap

torque

high torque

high torque density

Návrh lineárního oscilačního pohonu s vnitřním buzením / Design of linear internal excitation drive with oscillative motion

Kramář, Ondřej

January 2009

This thesis deals with design of linear internal excitation drive with oscillative motion. Here is shown the survey area of linear drives, as well as the field of patents which are involved in this issue. This work is proposed specific conception of linear internal excitation drive with oscillative motion which is verified by simulation of dynamic behavior and for which is also proposed a control. Design of linear internal excitation drive with oscillative motion, that meet the specified input parameters is a goal of this thesis.

Konstrukce multifunkčního obráběcího centra / Design of multi-functional machining centre

Cvejn, Jiří

January 2013

The purpose of this diploma thesis is a design of frame, crossbar, transverse feed, sliding feed of multifunctional machining center. In the first part, there is a brief research of history of machine tool conducted, division of machining centers, materials for frame construction, alternatives of drives of sliding axis. Further, I carry out an analysis of parameters of compeeting machine tools, from which I selected the parameters of our machine. Frame project of the machine, propulsion of axis X and Y, kinematic connection of axis X,Y,Z. Frame of machine is analysed by Finite Element Method. Over the scope of this work I suggest a solution for covering of linear axis as well as their measuring of actual position. 3D model of frame and drives of machine are included in this work. A complete formation has been introduced into the immersive virtual reality environment.

Efficient and high performing hydraulic systems in mobile machines

Frerichs, Ludger, Hartmann, Karl

January 2016

Hydraulic systems represent a crucial part of the drivetrain of mobile machines. The most important drivers of current developments, increasing energy efficiency and productivity, are leading to certain trends in technology. On a subsystem level, working hydraulics are utilizing effects by improving control functions and by maximum usage of energy recovery potential. Independent metering and displacement control, partly in combination with hybrid concepts, are the dominating approaches. Traction drives gain advantage from optimized power split transmissions, which consequently are being used in a growing number of applications. On the level of components, increase of efficiency and dynamics as well as power density are important trends. Altogether, design of systems and components is more and more based on modular concepts. In this sense, among others, sensors and control elements are being integrated to actuators; electric and hydraulic technology is being merged. In order to achieve maximum efficiency and performance of the entire machine, control of hydraulics has to include the whole drivetrain and the entire mobile machine in its application. In modern words, mobile hydraulic systems are a part of cyber physical systems.

info:eu-repo/classification/ddc/620

ddc:620

Från öppna hjärtan till stängda gränser : En fallstudie om drivkrafterna bakom Moderaternas förändrade migrationspolitik

Asp, August

January 2020

The past decade has been a relatively tumultuous time in Swedish parliamentary politics with minority governments, a new party challenging the status quo and ultimately the breaking of the second largest coalition in Swedish politics. The decade also saw some policy changes in parties, most strikingly the Moderate party which once an outspoken proponent of a lax immigration policy, saw a clear shift to a more restrictive policy after the 2015 refugee crisis. The first aim of this study is to explain what the shift in immigration policy looks like in terms of whether it was a positional change or a change in ideological emphasis too. By using the method of comparing manifestos the conclusion was reached that the Moderate party shifted both their positional policy and their ideological emphasis. The question of what drives political parties to change policy is a hotly debated one with a wide array of theories and perspectives contributing to the discussion. In addition this study also attempts to apply the theory first proposed by Harmel and Janda (1994) “An Integrated Theory of Party Goals and Party change” on the Moderate party to explain the driving force behind the shift in immigration policy. This was done by comparing Moderate party manifestos from the year 2006 to 2018 in three issues (immigration, private actors in the education sector and private actors in the healthcare sector) that saw the public opinion clearly shift away from the party. Mostly through the process of elimination the study concludes that the Moderate party likely shifted their position on immigration issues in order to have better chances of forming more advantageous coalitions in order to change their opposition status in the future.

Party politics

Policy shifts

party drives

vote maximizer

office maximizer

policy advocates

democracy maximizer

Moderate party

Sweden

immigration

Political Science

Statsvetenskap