Your search keyword '"Takeshi Mizuno"' showing total 1,023 results

1. Characteristic analysis and performance improvement of differentially-operated three-dimensional optical displacement sensor

Author

Takeru MOMOKI, Takeshi MIZUNO, Masaya TAKASAKI, and Yuji ISHINO

Subjects

displacement sensor, wind-tunnel, magnetic suspension, optical sensor, three-dimensional measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

The characteristics of a differentially-operated optical displacement sensor developed for wind-tunnel using magnetic suspension are studied both analytically and experimentally. The target sensor measures the three-dimensional displacement of the suspended object (floator) from the variations of the shadow of the floator. It is composed of eight optical systems. First, the output characteristics of the fabricated sensor are measured. As to linearity, it is good in the direction of light (x-axis) but inferior in the other directions (y and z axes). In addition, interferences among the axes are observed. Because the differences in characteristics among the optical systems cause such errors, adjustments by software are carried out. They reduce the nonlinearity and interferences. However, residual errors still remain. To clarify the reasons, the output characteristics are studied analytically by investigating the movement of the shadow of the floator and the variations of the illuminated area on the lenses. The results suggest that nonlinearity and interaxial interferences exist on some extent in the sensor, which was observed in the experiments.

Published

2024

2. Introduction of DC magnetic suspension to AC magnetic suspension using magnetic resonant coupling

Author

Takuma KOBAYASHI, Takeshi MIZUNO, Masaya TAKASAKI, and Yuji ISHINO

Subjects

magnetic suspension, magnetic bearings, magnetic resonant coupling, power transfer, self-stabilization, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

DC magnetic suspension operated by transmitted power is introduced to AC magnetic suspension system using magnetic resonant coupling for dynamic stabilization. The target AC magnetic suspension system has a self-stabilization property. Although restoring force is produced without active control in this system, damping is necessary for dynamic stabilization. To generate damping force, a DC magnetic suspension mechanism, which is operated by the power transmitted to the floator through magnetic resonant coupling, is installed in parallel with the AC magnetic suspension mechanism. The newly developed system has a pair of AC electromagnets and another pair of DC electromagnets. The former pair generates positive stiffness according to the self-stabilization property. The latter pair is expected to produce positive damping by shortening the coil of the electromagnet on the stator. However, it is experimentally shown that negative damping is produced because the latter pair also has the self-stabilization property. Therefore, a bias voltage is applied to the DC electromagnet on the stator to make the stiffness negative. As a result, stable suspension is achieved without active control in the developed system. However, the overall stiffness decreases and the stability range is small because the latter pair has negative stiffness. To solve such a problem, a phase-lead compensation is applied to the latter pair instead of the bias voltage. This method can produce positive damping and positive stiffness at the same time so that the suspension characteristics are improved.

Published

2024

3. Application of Biosheets as Right Ventricular Outflow Tract Repair Materials in a Rat Model

Author

Takeshi Mizuno, Ryosuke Iwai, Takeshi Moriwaki, and Yasuhide Nakayama

Subjects

in-body tissue architecture, congenital heart defect, rat model, tissue engineering, autologous tissue membrane, Veterinary medicine, SF600-1100

Abstract

PurposesWe report the experimental use of completely autologous biomaterials (Biosheets) made by “in-body tissue architecture” that could resolve problems in artificial materials and autologous pericardium. Here, Biosheets were implanted into full-thickness right ventricular outflow tract defects in a rat model. Their feasibility as a reparative material for cardiac defects was evaluated.MethodsAs the evaluation of mechanical properties of the biosheets, the elastic moduli of the biosheets and RVOT-free walls of rats were examined using a tensile tester. Biosheets and expanded polytetrafluoroethylene sheet were used to repair transmural defects surgically created in the right ventricular outflow tracts of adult rat hearts (n = 9, each patch group). At 4 and 12 weeks after the operation, the hearts were resected and histologically examined.ResultsThe strength and elastic moduli of the biosheets were 421.3 ± 140.7 g and 2919 ± 728.9 kPa, respectively, which were significantly higher than those of the native RVOT-free walls (93.5 ± 26.2 g and 778.6 ± 137.7 kPa, respectively; P < 0.005 and P < 0.001, respectively). All patches were successfully implanted into the right ventricular outflow tract-free wall of rats. Dense fibrous adhesions to the sternum on the epicardial surface were also observed in 7 of 9 rats with ePTFE grafts, whereas 2 of 9 rats with biosheets. Histologically, the vascular-constructing cells were infiltrated into Biosheets. The luminal surfaces were completely endothelialized in all groups at each time point. There was also no accumulation of inflammatory cells.ConclusionsBiosheets can be formed easily and have sufficient strength and good biocompatibility as a patch for right ventricular outflow tract repair in rats. Therefore, Biosheet may be a suitable material for reconstructive surgery of the right ventricular outflow tract.

Published

2022

4. Case Report: Tricuspid Annuloplasty for Right-Sided Congestive Heart Failure Secondary to Pulmonary Hypertension in a Dog

Author

Takeshi Mizuno, Kenta Sasaki, Sayaka Suzuki, Itsuma Nagao, and Noriko Isayama

Subjects

De Vega annuloplasty, cardiopulmonary bypass, tricuspid regurgitation, ascites, dog, Veterinary medicine, SF600-1100

Abstract

An 11-year-old, 12.3-kg, female Miniature Dachshund was presented to our institution with ascites of unknown etiology. The dog had been administered moxidectin for 3 years to treat a heartworm infection. Thoracic radiographs showed enlargement of the right heart. Echocardiography revealed right atrial and ventricular dilatation as well as flattening of the interventricular septum. Heartworm was identified in the main pulmonary artery, which was dilated. Tricuspid regurgitation (TR) was observed using color Doppler ultrasonography, and 2.5 L of ascites were removed. The dog was diagnosed with pulmonary hypertension, severe TR, and right-sided congestive heart failure. Except at the initial site, heartworm was not detected using echocardiography, and the antigen test was negative. However, pharmacological treatment did not improve the right-sided congestive heart failure. Instead, De Vega tricuspid annuloplasty (TAP) was performed on the beating heart under cardiopulmonary bypass with the owner's consent. Sutures terminated between the two commissures in the middle of the annulus and were secured using another pledget. Annular reduction was performed by tying down the plication suture while the cylindrical sizer was inserted into the tricuspid valve orifice. The size of the cylindrical sizer was 16 mm, which was set based on the height and width of the septal leaflet. A 6-month follow-up showed a reduction of TR and right-sided volume overload with no evidence of ascites retention/recurrence or any other complication. Our findings indicate that TAP may be a valid treatment option for dogs with right-sided congestive heart failure caused by secondary TR.

Published

2022

5. Mass estimation considering stiffness and fabrication of period measurement device in mass measurement using velocity-feedback relay control

Author

Takeshi MIZUNO, Taku EGAWA, Masaya TAKASAKI, and Yuji ISHINO

Subjects

measurement, nonlinear control, self-excited vibration, electromagnetic actuator, motion control, vibration control, mass measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A mass measurement system with a relay feedback of velocity has been developed to achieve measurement without gravity. In this system, mass is estimated from the periods of oscillation in the relay-feedback system. Originally, the velocity of the object was solely fed back, which caused the orbit of the object to drift easily. A restoring force compensation by a spring was introduced to avoid such drift. However, a slight drift still occurs in spite of the restoring force element. A new estimation formula has been derived which can estimate mass regardless of the position of the closed orbit. An analytical study on this formula shows that mass is overestimated when the restoring force is neglected in the estimation. Several experimental results show that the estimated mass is slightly larger than the actual value even though the new formula is used in estimation. In the measurement, the periods of oscillation are measured with a digital oscilloscope. A delay in the period measurement is expected to cause such overestimation. To reduce the error due to delay in measuring periods, a new device for rapid period measurement is developed, which uses the edge detecting function of a micro-computer. It is experimentally demonstrated that the measurement error is reduced by the developed measurement device.

Published

2021

6. Position-insensitive estimation of mass from limit cycle of velocity feedback relay system with Spring

Author

Takeshi Mizuno, Taku Egawa, Masaya Takasaki, and Yuji Ishino

Subjects

Control engineering systems. Automatic machinery (General), TJ212-225, Technology (General), T1-995

Abstract

Mass measurement using relay feedback of velocity and restoring force compensation is investigated for determining the mass of an object under weightless conditions. In the measurement system, the velocity of the object is fed back through a relay with hysteresis and the force acting on the object is switched from a positive value to a negative value when the velocity reaches a positive threshold and vice versa. As a result, a limit cycle is induced in the measurement system and the mass is estimated based on the period of the limit cycle. In addition, restoring force compensation with a spring is introduced to avoid the drift of the trajectory. This compensation makes the static equilibrium state unique. However, the trajectory still drifts slightly. It causes some error in measurement when a simple formula of estimating mass is applied. To eliminate such an error, a new formula is derived to estimate the mass independently of the position of the trajectory that is determined by the switching positions in the relay actions. When the switching positions deflect from the origin at which the spring is in the natural length, the trajectory is not at the center and becomes asymmetric. It is analytically shown that the period of the limit cycle is minimum when the switching positions are at the origin. It indicates that mass is overestimated with the simple estimation formula when the trajectory is not at the center. The validity of the modified formula and the analytical results are confirmed experimentally.

Published

2021

7. Development of MEMS-based micro-force measurement system with zero-compliance mechanism

Author

Ryu MONJIYAMA, Takeshi MIZUNO, Yuji ISHINO, and Masaya TAKASAKI

Subjects

force measurement, micro force, mems, zero-compliance mechanism, feedback control, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A miniaturized force measurement device with zero-compliance mechanism is designed and fabricated using MEMS technology. Zero-compliance mechanism consists of two suspensions connected in series through a detection point. When a force is applied to an object suspended by this mechanism, the position of the object can be kept constant by controlling the detection point. Furthermore, the force can be estimated from the displacement of the detection point because the displacement of the detection point is proportional to the force. The measurement method using zero-compliance mechanism is effective for measuring interatomic force, which is usually a function of the gap between objects. This work focuses on the miniaturization of this mechanism by MEMS technology. An experimental device is designed and fabricated. This device consists of comb-drive actuators, capacitance sensors using comb electrodes and leaf springs. It is experimentally confirmed that zero-compliance can be realized in such a miniature device fabricated using MEMS technology. In addition, measurement performances are improved in the device.

Published

2021

8. Realization of Stable Trajectory in Mass Measurement System Using Relay Feedback of Velocity and Restoring Force Compensation

Author

Takeshi Mizuno, Keisuke Nishizawa, Masaya Takasaki, Yuji Ishino, Masayuki Hara, and Daisuke Yamaguchi

Subjects

mass measurement, limit cycle, relay feedback, pulse width modulation, stiffness, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

A mass measurement system using relay feedback of velocity was developed. In this system, the velocity of the object was fed back through a relay with hysteresis. Although the efficacy of the proposed method has been already confirmed experimentally, it was subject to a drift mainly because only the velocity was fed back. To prevent such a drift, a spring element was added to produce restoring force. However, smaller drifts still occurred, and the trajectory of the object fluctuated. To eliminate such fluctuations, intermediate control is introduced. It succeeds to eliminate fluctuation of the trajectory in the developed apparatus.

Published

2019

9. Experimental Study on Magnetic Resonant Coupling AC Magnetic Suspension Considering Electrical Power Transmission

Author

Yuji Ishino, Takeshi Mizuno, and Masaya Takasaki

Subjects

magnetic suspension, magnetic bearings, magnetic resonant coupling, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

A three-degree-of-freedom AC magnetic suspension system using magnetic resonant coupling was fabricated. The AC magnetic suspension system can produce restoring force without active control. This system is dynamically stabilized by adding indirect damping, which is produced by suspending to the stator with viscoelastic support mechanisms. A non-contact electrical power transmission is achieved simultaneously by magnetic resonant coupling. The structure of magnetic resonant coupling is similar to the structure of the transformer. The magnetic flux path for suspension is combined with that of electrical power transmission. The electric characteristics of the transformer depend on the resistance of a load connecting the secondary circuit. The measured results indicate that the driving frequency needs to be adjusted to achieve stable suspension in relation to the resistance of the load. These characteristics are confirmed experimentally.

Published

2022

10. Study of dual-mass dynamic vibration absorber with negative-stiffness interaction between masses

Author

Kenji TOMITA, Takeshi MIZUNO, Yuji ISHINO, and Masaya TAKASAKI

Subjects

dynamic vibration absorber, vibration, vibration control, negative-stiffness, anti-resonance frequency, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

An interaction through a negative-stiffness spring is introduced into a dual-mass dynamic vibration absorber (DVA) to lower its resonance frequency. DVA is one of the practical vibration control devices. In principles, it consists of an absorption mass and a spring. It can eliminate vibration at a specified frequency that equals the resonance frequency of the DVA. To eliminate low-frequency vibration, it is necessary to increase the absorption mass or lower the spring constant. The former method increases the size of the device and the latter method may cause difficulty in supporting the absorption mass. Although there are reports on the optimal design and robust optimal design of DVAs, there are few reports that focus on lowering the anti-resonance frequency. In addition, there are few studies on the parallel dual-mass DVA that has interference between the vibration absorption masses. This work focuses on parallel dual-mass DVA and proposes to insert a negative spring between the absorption masses. It is analytically shown that one of the resonance frequencies of the DVA can be set lower than that of the conventional DVA. Such characteristics are confirmed by numerical analyses and experiments.

Published

2020

11. Stabilization of magnetic suspension system by a reset element (Adjustment of vibration attenuation characteristic)

Author

Yuji ISHINO, Takeshi MIZUNO, Masaya TAKASAKI, and Daisuke YAMAGUCHI

Subjects

magnetic lavitation, magnetic bearing, electromagnetic actuator, motion control, non-linear control, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A first-order-reset element (FORE) controller is modified to adjust the vibration attenuation characteristic of a magnetic suspension system. The proportional-derivative (PD) feedback control is the simplest control method of stabilizing magnetic suspension systems. In the PD-controlled system, restoring force is produced with the proportional element and damping effect is produced with the derivative element. Meanwhile, a feedback control using a FORE has been proposed to stabilize magnetic suspension systems. The FORE replaces a linear integrator built into a first-order low-pass filter by a non-linear integrator. The proposed controller can stabilize a magnetic suspension system with one element. The restoring force and damping effect are generated simultaneously. However, the two effects could not be adjusted separately. To adjust the vibration attenuation characteristic, the FORE controller is modified to adjust the transition value at reset. The characteristics of the modified controller are studied through numerical analysis. Then the effectiveness of the modification is demonstrated by several simulations and experiments.

Published

2020

12. Development of bilateral operation system for the assembly of magnetized components

Author

Ryu MONJIYAMA, Takeshi MIZUNO, Yuji ISHINO, Masaya TAKASAKI, and Daisuke YAMAGUCHI

Subjects

bilateral control, master-slave system, position control, observer, disturbance estimation, magnet, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

In the assembly of micro components, a slight impact during assembly affects product performance. This work focuses on the assembly of parts including magnetized components. In the assembly of such parts, the attractive force acting between the parts causes a difficulty of assembly without collision. For this reason, such a work is conducted by skilled workers. However, the lack of successors has become a problem. Therefore, a bilateral operation system is developed for training such successors. A bilateral control is installed using two devices including a voice coil motor, a leaf spring and a sensor. The slave device is controlled to follow the motion of the master device. The force applied to the slave device is estimated with a full order observer to reflect the force on the master device. It is confirmed experimentally that the slave device can follow the master device and that the force applied by the slave device can be presented to the master device. In addition, assembling experiments are conducted using the bilateral operation system. The displacement of each device and the applied external force to slave device are obtained. It is demonstrated that the assembling technique could be evaluated quantitatively.

Published

2020

13. Force Measurement Using Zero-Compliance Mechanism

Author

Takeshi Mizuno, Yuji Ishino, Hiroki Kawada, Yoichiro Hayashi, Masaya Takasaki, Masayuki Hara, and Daisuke Yamaguchi

Subjects

force measurement, zero compliance, infinite stiffness, servomechanism, magnetic suspension, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

Force measurement using zero-compliance mechanism is proposed and studied experimentally. A zero-compliance mechanism is composed of two suspensions connected in series; one of them is operated to cancel the deflection of the other so that the total length of the suspension is maintained even if force acts between the ends. In the proposed measurement system, one of the ends becomes the point of force and the point of the connection becomes the detection point. The force is estimated from the displacement of the detection point. An apparatus is fabricated for experimental study to show the validity of the proposed measurement method. Double series magnetic suspension is used to achieve zero compliance. In the apparatus, the motions of two suspended objects (floators) are controlled with a single electromagnet. Each floator is supported by leaf springs to move in the vertical direction translationally. The attractive force of the electromagnet directly acts on the first floator in which a permanent magnet is installed. The motion of the second floator is controlled indirectly through the attractive force of the permanent magnet. To achieve the zero compliance characteristic, PID control is applied to the second floator. It is confirmed experimentally that the deflection of the second suspension, i.e., the distance between the first and second floators, is proportional to external force acting on the second floator. This result indicates that the force can be estimated for the deflection of the second suspension. It is also demonstrated that dynamic force can be measured by the proposed method.

Published

2018

14. Fabrication of a Polyimide Film Pneumatic Actuator by Molding and Welding Processes

Author

Daisuke Yamaguchi, Tatsuya Hanaki, Yuji Ishino, Masaya Takasaki, and Takeshi Mizuno

Subjects

soft robotics, pneumatic actuator, film, molding, welding, polyimide, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

The bellows pneumatic actuator, which is made by folding a non-stretch film, has been proposed for various applications because it is easy to fabricate and is extremely thin and light. However, it has subpar durability performance, especially in the folded part of the film. In this study, we propose an actuator with a pod structure that possesses high design flexibility and is free from folding. A method of molding a pod structure on a polyimide film was established and a pneumatic actuator was successfully fabricated by using PI films. Two types of PI film pneumatic actuators with the same curvature, bellows type, and pod type were fabricated. Both were confirmed to have equivalent output characteristics. The bending angle and generated torque of the pod-structure actuator were 34° and 3.3 mNm, respectively. In addition, the pod structure has approximately twice the durability of the bellows structure. By using the fabrication method proposed in this paper, it is possible to realize an air chamber (i.e., an actuator) that has both high durability and bending motion.

Published

2021

15. Vibration control of cryopump with an active dynamic vibration absorber

Author

Takeshi MIZUNO, Takahito IIDA, Yuji ISHINO, Masaya TAKASAKI, Masayuki HARA, Daisuke YAMAGUCHI, and Takeshi KANO

Subjects

cryopump, active dynamic vibration absorber, vibration control, internal model principle, low frequency, pole assignment, output regulation, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A vibration isolation device with an active dynamic vibration absorber is developed to remove vibration induced by a cryopump. Cryopump is used to make high-vacuum and low-temperature environments for precise measurement. However, it induces vibrations with multiple frequencies, which may deteriorate measurement accuracy. This study focuses on removing the vibration of low frequencies because conventional vibration isolation devices for cryopump can hardly remove them. In the developed vibration isolation device, an active vibration absorber is used to remove the vibration efficiently at low frequencies. The controller is designed based on the internal model principle. The pole assignment is used to tune the controller. The efficacy of the designed and tuned controller is demonstrated in the developed apparatus.

Published

2019

16. Development of a three-degree-of-freedom control magnetic suspension system using laterally control flux-path mechanisms

Author

Naoki ISHIBASHI, Takeshi MIZUNO, Yuji ISHINO, Masaya TAKASAKI, and Daisuke YAMAGUCHI

Subjects

magnetic bearing, magnetic levitation, electromagnetic actuator, permanent magnet, flux-path control, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A magnetic suspension system with three flux-path control mechanisms are developed to achieve three-dimensional positioning of the suspended object (floator). In the flux-control mechanism, a ferromagnetic control plate is located in the lateral direction of the magnetic source (permanent magnet). It was shown that the attractive force acting on the floator could be varied by moving the control plate in the vertical direction. In addition, the lateral force was generated by using two control plates located on both sides of the floator and moving them differentially. In this work, an apparatus is fabricated which has three flux-path control mechanisms. The configurations of the apparatus are described. Stable suspension is achieved and basic characteristics are studied. In addition, 3-degree-of-freedom (3-DOF) control suspension is achieved by moving three control plates individually. The 3-DOF control is evaluated by moving the floator in circular orbits.

Published

2018

17. Physics of Strongly-coupled Dopant-atoms in Nanodevices

Author

Daniel Moraru, Krzysztof Tyszka, Yuki Takasu, Arup Samanta, Takeshi Mizuno, Ryszard Jablonski, and Michiharu Tabe

Subjects

Dopant atoms, Nanoscale, Quantum dot, Silicon, Tunneling transport, Technology, Technology (General), T1-995

Abstract

In silicon nanoscale transistors, dopant atoms can significantly affect the transport characteristics, in particular at low temperatures. Investigation of coupling between neighboring dopants in such devices is essential in defining the properties for transport. In this work, we present an overview of different regimes of inter-dopant coupling, controlled by doping concentration and a selective doping process. Tunneling-transport spectroscopy can reveal the fundamental physics of isolated dopants in comparison with strongly-coupled dopants. In addition, observations of surface potential for Si nano-transistors can provide direct access to understanding the behavior of coupled dopants.

Published

2015

18. An Equivalent Circuit Analysis and Suspension Characteristics of AC Magnetic Suspension Using Magnetic Resonant Coupling

Author

Arifur Rahman, Takeshi Mizuno, Masaya Takasaki, and Yuji Ishino

Subjects

AC magnetic suspension, magnetic resonance coupling, equivalent magnetic and electrical circuit, positive stiffness, mutual inductance, self-stabilization, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

The fundamental characteristics and performances of alternating current (AC) magnetic suspension using magnetic resonant coupling are studied analytically and experimentally. Nowadays, wireless power transfer to the suspended object is required during non-contact suspension in some applications. Therefore, magnetic resonant coupling has been introduced for AC magnetic suspension to achieve self-stabilizing magnetic suspension and energy transfer to the floator simultaneously. The effect of circuit parameters for developing an experimental apparatus and performances are predicted from the solution of the equivalent circuits analytically. First, an equivalent magnetic circuit is derived and analyzed to characterize the self-inductance and mutual inductance with the gap. Second, an equivalent electrical circuit is analyzed to derive the current and force equations including magnetic parameters of the circuit. The derivation of these equations is numerically solved to study the characteristics of the primary current, the secondary current, and the force with respect to the gap and the applied frequency. The comparison between theoretical and experimental results is depicted, and the reason for differences is explained. The experimental and theoretical results show that positive stiffness is possible, which is essential for achieving self-stabilization. The self-stability is confirmed by the frequency response of the suspension system to disturbance experimentally.

Published

2020

19. Basic characteristics of a parallel magnetic suspension system controlling two-degree-of-freedom motions

Author

Yoshinori NARISAWA, Takeshi MIZUNO, Masaya TAKASAKI, Yuji ISHINO, Masayuki HARA, and Daisuke YAMAGUCHI

Subjects

magnetic bearing, magnetic levitation, mechatronics, motion control, parallel suspension, two-degree-of-freedom system, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A basic single-degree-of-freedom magnetic suspension system consists of one floator, one electromagnet and one amplifier. For multi-degrees-of-freedom control, multiple electromagnets and multiple amplifiers are necessary, which increases the cost of total system. As a means of overcoming this problem, parallel magnetic suspension has been proposed which controls multiple floators or multi-degree-of-freedom motions with a single power amplifier. In this system, all of the suspended points move simultaneously even when a disturbance acts on one of the suspended points solely because all electromagnet's coils are connected. This paper studies the moving direction of each suspended point with respect to a step disturbance in double parallel magnetic suspension system. The analytical study shows that the response direction is determined by the system parameter that relates the response speed of each subsystem. In the slower subsystem, the suspended point moves in the same direction as the applied force while in the faster subsystem, the suspended point moves in the opposite direction. In other words, the slower subsystem has positive stiffness while the faster system has negative stiffness. To confirm this prediction, step responses are measured in the experimental apparatus.

Published

2018

20. Validation of multi-dimensional force measurement using zero-compliance mechanism

Author

Md Helal An NAHIYAN, Takeshi MIZUNO, Masaya TAKASAKI, Yuji ISHINO, Masayuki HARA, and Daisuke YAMAGUCHI

Subjects

zero compliance, magnetic balance, force measurement, infinite stiffness, series suspension, electromagnetic force, Engineering machinery, tools, and implements, TA213-215, Mechanical engineering and machinery, TJ1-1570

Abstract

A novel force measurement instrument is designed and fabricated to validate multi-dimensional force measurement using zero compliance mechanism. In each axis, there is a point of force and a detection point for zero-compliance force measurement. Both the detection point and the point of force are suspended in series and attached with the base frame through leaf springs. When external force is applied at the point of force, it moves from its original position. The motion of the point of force can be regulated by displacing the detection point in the same or opposite direction of the applied force. The control system is designed and implemented to control the movement of the point of force and the detection point in vertical and horizontal direction force measurement. The effect of applied force on the point of force is cancelled to maintain its position by displacing the detection point. The motion of the detection point is controlled in such a way that it displaces proportionally to the applied force. Thus, applied force can be estimated from the displacement of the detection point and zero-compliance is accomplished at the point of force. The effectiveness of the proposed instrument in multi-dimensional force measurement is demonstrated by the experimental results of the horizontal and vertical direction force measurement with good linearity and almost zero interference.

Published

2018

21. Lateral vibration control in attractive magnetic suspension system

Author

Takeshi MIZUNO, Asief JAVED, Yuji ISHINO, and Masaya TAKASAKI

Subjects

magnetic bearing, magnetic levitation, vibration control, nonlinear control, electromagnetic actuator, variable stiffness, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A switching stiffness control and a modified variable stiffness control were applied to reduce vibration in the lateral directions in active magnetic suspension system with electromagnets operated in the differential mode. The magnetic suspension system using the attractive force between magnetized bodies is inherently unstable in the normal direction so that feedback control is necessary to achieve stable suspension. In contrast, it is usually stable in the lateral directions because of the edge effects in the magnetic circuits. However, damping in the lateral directions is poor so that vibration is easily induced. In this work, a switching stiffness control was applied to attenuate such vibration. The effectiveness of the switching stiffness control was confirmed experimentally. In addition, a modified control method that varies stiffness continuously was proposed to overcome problems occurring in switching. The efficacy of the modified control method was also confirmed experimentally.

Published

2017

22. Positive-pressure driven overflow-prevention valve with compact trigger mechanism

Author

Takeshi MIZUNO, Yuji ISHINO, and Masaya TAKASAKI

Subjects

oil and air hydraulics, pneumatic equipment, material handling equipment, valve, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A new over-flow prevention valve with a trigger mechanism is designed, fabricated and studied experimentally to evaluate its performances. Loading arms are used to transfer combustible fluid such as oil between tankers and tanks. A loading arm is equipped with an over-flow prevention valve for safety. This valve stops the fluid flow when the fluid exceeds a threshold level in a tank. It must be composed of mechanical elements solely because electric components may induce combustion. Therefore, it uses a pneumatic circuit to detect the fluid level and close the valve. The fabricated valve utilizes positive pressure caused by the height difference of fluid level between the tank and the sensor probe instead of negative pressure that was used in a conventional valve. However, the positive pressure is insufficient to close the valve directly. Therefore, a trigger mechanism is introduced between a piston pushed by the positive pressure and a locking mechanism keeping the valve open. This mechanism generates sufficient force to release the lock and close the main valve from the force pushing the piston. The concept, operation principles and the pneumatic circuit design are presented. Experiments simulating actual operation are carried out with the fabricated valve. The sensor probe is inserted into the water with a constant speed by a single-axis robot instead of flowing oil into the tank. The relation between the velocity and the depth when the valve closes are studied experimentally.

Published

2017

23. Development of a wind-tunnel for spinning body using magnetic suspension

Author

Takeshi MIZUNO, Yasuhiro SAKAI, Masaya TAKASAKI, and Yuji ISHINO

Subjects

magnetic suspension, spinning body, wind-tunnel, hydrodynamic force measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A wind-tunnel system for spinning body has been proposed to measure hydrodynamic forces acting on the body. In the proposed system, the body is suspended and rotated by electromagnets. The forces are measured from the control signal for suspension. In the previously fabricated apparatus, eight electromagnets were placed around a wind-tunnel. An optical displacement sensor was used to detect the three-dimensional positions of the body. Stable suspension and three-dimensional positioning of the body were achieved. However, it had several problems; the test section area was rather small and vibration was induced by flowing wind to the floator. To solve such problems, a new wind-tunnel using magnetic suspension is developed. It has two and a quarter times test section area. The position sensor is improved to operate in a differential mode in all the directions. Stable suspension and rotation of the floator are achieved. The floator is kept stably without vibration even in the face of wind. The hydrodynamic forces acting on the spinning floator are measured.

Published

2017

24. Study on the delay of velocity detection and derivation of a correction formula in mass measurement using relay feedback

Author

Naoki ISHIBASHI, Takeshi MIZUNO, Yuji ISHINO, Masaya TAKASAKI, Daisuke YAMAGUCHI, Masayuki HARA, and Rei WATANABE

Subjects

mass measurement, relay feedback control, self-excited oscillation, limit cycle, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

This paper treats a relay-feedback mass measurement system that uses a relay with hysteresis and feeds back the velocity of the object. The measurement system has an on-off relay with hysteresis and switches force acting on the object in relation to its velocity. Such nonlinear control induces a limit cycle. The mass of the object is determined from the period of this cycle. In previous study, the actual trajectory of the limit cycle was different in shape from the theoretical one so that the prerequisites of the estimation formula were not satisfied. The delay of the velocity sensor is a main factor of such degradation. In this paper, the effect of the delay on mass estimation is investigated experimentally and analytically. In addition, an estimating equation including this effect is derived. Experimental result supports the validity of the derived estimating equation.

Published

2017

25. Realization of two-degree-of-freedom motions control using parallel magnetic suspension

Author

Yoshinori NARISAWA, Takeshi MIZUNO, Masaya TAKASAKI, Masayuki HARA, Daisuke YAMAGUCHI, and Yuji ISHINO

Subjects

magnetic bearing, magnetic levitation, mechatronics, motion control, parallel suspension, two-degree-of-freedom system, controllability, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Parallel magnetic suspension has been proposed which levitates multiple floators with a single power amplifier. This study applies this concept to a multi-degree-of-freedom system. In such systems, multiple electromagnets are used to stabilize multi-degree-of-freedom motions of the floator. In conventional system, each electromagnet is driven by the corresponding power amplifier. In contrast, multiple electromagnets are driven by a single power amplifier simultaneously in the case of parallel magnetic suspension. This study shows the feasibility of multi-degree-of-freedom control with a single power amplifier. First, the controllability of two-degree-of-freedom system controlled by parallel magnetic suspension is discussed. Second, an experimental apparatus is fabricated in which the vertical translational motion and the rotational motion around a horizontal axis are controlled by two pairs of electromagnets operated in a differential mode. Third, stable levitation is achieved in the apparatus. In addition, the dynamic characteristics are evaluated based on step response and frequency response with respect to external force. It is observed that the two suspended points vibrate in common phase with respect to the disturbance in a low-frequency region.

Published

2017

26. A New Direct Single-Molecule Observation Method for DNA Synthesis Reaction Using Fluorescent Replication Protein A

Author

Shunsuke Takahashi, Shohei Kawasaki, Hidefumi Miyata, Hirofumi Kurita, Takeshi Mizuno, Shun-ichi Matsuura, Akira Mizuno, Masahiko Oshige, and Shinji Katsura

Subjects

single-molecule observation, single-stranded DNA, replication protein A (RPA), DNA polymerase, DNA synthesis, Chemical technology, TP1-1185

Abstract

Using a single-stranded region tracing system, single-molecule DNA synthesis reactions were directly observed in microflow channels. The direct single-molecule observations of DNA synthesis were labeled with a fusion protein consisting of the ssDNA-binding domain of a 70-kDa subunit of replication protein A and enhanced yellow fluorescent protein (RPA-YFP). Our method was suitable for measurement of DNA synthesis reaction rates with control of the ssλDNA form as stretched ssλDNA (+flow) and random coiled ssλDNA (−flow) via buffer flow. Sequentially captured photographs demonstrated that the synthesized region of an ssλDNA molecule monotonously increased with the reaction time. The DNA synthesis reaction rate of random coiled ssλDNA (−flow) was nearly the same as that measured in a previous ensemble molecule experiment (52 vs. 50 bases/s). This suggested that the random coiled form of DNA (−flow) reflected the DNA form in the bulk experiment in the case of DNA synthesis reactions. In addition, the DNA synthesis reaction rate of stretched ssλDNA (+flow) was approximately 75% higher than that of random coiled ssλDNA (−flow) (91 vs. 52 bases/s). The DNA synthesis reaction rate of the Klenow fragment (3’-5’exo–) was promoted by DNA stretching with buffer flow.

Published

2014

27. Pump using ultrasonic transducer and opposing surface (1st report : observation of pump effect)

Author

Hiroaki SHINADA, Yuji ISHINO, Daisuke YAMAGUCHI, Masayuki HARA, Masaya TAKASAKI, and Takeshi MIZUNO

Subjects

ultrasonic pump, opposing block, taper, squeeze film, ultrasonic transducer, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Currently, pumps are used in various fields to supply air and liquid. These pumps include sliding parts and there is a limit of life time due to friction and wear. To solve this problem, a number of pumps using ultrasonic vibration have been proposed. A common feature of ultrasonic pumps is having no sliding parts. Therefore, the life time seems longer than those of the conventional pumps. In the present study, we found an occurrence of pump effect when an opposing block faces ultrasonically vibrating surface with a small gap. The ultrasonic transducer has a hole to provide the path for fluid flow and the opposing surface was a tapered end of an aluminum cylinder. According to the measurement results of gauge pressure, when circumference of the opposing block is tapered, air was discharged from the gap of two surfaces. On the other hand, when center of the block is tapered, air was sucked into the gap. Microscopic quasi-static behavior of the two surfaces is observed by using a digital microscope during pump operation.

Published

2016

28. Stabilization of Magnetic Suspension System by Using Only a First-Order Reset Element without a Derivative Element

Author

Yuji Ishino, Takeshi Mizuno, Masaya Takasaki, and Daisuke Yamaguchi

Subjects

magnetic suspension, nonlinear controller, reset control, Clegg’s integrator, first-order reset element, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

The stabilization of a magnetic suspension system is achieved by using a low-pass filter (LPF) with a nonlinear integrator without any other element. A proportional-derivative (PD) control is commonly used as the simplest method of stabilizing a magnetic suspension system. Meanwhile, a first-order reset element (FORE) was applied to improve transient characteristics. The original FORE was a first-order LPF with a nonlinear reset integrator element. A magnetic suspension system cannot be stabilized by a linear LPF, nor the original FORE. In this work, the reset conditions of the FORE were modified for magnetic suspension. This modified FORE succeeded in stabilizing a magnetic suspension system. The efficacy of the modified FORE was demonstrated by simulations and experiments. A single degree of freedom magnetic suspension system was used in the experiment.

Published

2019

29. Modeling and Validation of Vertical Direction Force Estimation with a Three-Dimensional Force Measurement Instrument Based on a Zero-Compliance Mechanism

Author

Md Helal An Nahiyan, Takeshi Mizuno, Masaya Takasaki, Yuji Ishino, Masayuki Hara, and Daisuke Yamaguchi

Subjects

zero-compliance, force measurement, electromagnetic force, magnetic balance, series suspension, Chemical technology, TP1-1185

Abstract

The principle of a zero-compliance mechanism was used to develop a three-dimensional force measurement instrument. In each axis, the point of force is suspended by a zero-compliance mechanism. A vertical axis force estimation operation imitates the structure of a double series magnetic suspension system. An electromagnet directly controls the movement of the first suspended object (floator), which is denoted as a detection point, and indirectly controls the motion of the second floator, which is denoted as a point of force. Indirect control of the point of force is executed by the attractive force of a permanent magnet that is fixed to the bottom part of the detection point. To achieve zero-compliance, a Proportional-Integral-Derivative (PID) control is applied to the point of force, and to make the system stable, a Proportional-Derivative (PD) control is also applied to the detection point. In such suspension conditions, when force is exerted on the point of force, the displacement of the second floator is regulated to maintain its primary position while the detection point displaces in proportion to the applied force. Thus, a zero-compliance condition is maintained at the point of force, and the external force is measured from the linear displacement of the detection point. To restrict the motions of the detection point and the point of force in translation only, they are supported with leaf springs. This paper presents the modeling of the vertical direction force measurement operation of the developed three-axis force estimation instrument, and the theoretical analyses were validated by experiments of force measurement in both the millinewton and micronewton ranges.

Published

2019

30. Novel AC magnetic suspension using magnetic resonant coupling

Author

Takeshi MIZUNO, Kei TAKAHASHI, Yuji ISHINO, and Masaya TAKASAKI

Subjects

magnetic bearing, magnetic levitation, mechatronics, electromagnetic actuator, stability, Mechanical engineering and machinery, TJ1-1570

Abstract

A novel alternate-current (AC) magnetic suspension using magnetic resonant coupling is proposed and studied both theoretically and experimentally. An AC magnetic suspension with energy transfer function has been developed to achieve magnetic suspension and energy transfer to the suspended object simultaneously. However, the energy transfer efficiency was low in the developed system mainly because there existed a rather wide gap between the primary and secondary circuits. In contrast, the energy transfer technique using magnetic resonant coupling has high efficiency even if there is a wide gap. In this work, this technique is combined with AC magnetic suspension. The fundamental characteristics of the proposed system are studied for a basic model. It is shown analytically that the coupled circuits has two resonant frequencies and attractive force is generated at the lower resonant frequency while repulsive force is generated at the higher resonant frequency. In addition, the self-stabilizing characteristic, which is proper in the tuned LCR circuit levitation, is achievable in the proposed suspension system. A see-saw type experimental apparatus was fabricated for basic experimental study. The theoretical predictions were confirmed experimentally. The self-stabilization was achieved in the fabricated apparatus. It was also shown experimentally that the stiffness and damping characteristics depend on the gap, the amplitude and frequency of the AC voltage source.

Published

2016

31. Individuality of Dopants in Silicon Nano-pn Junctions

Author

Daniel MORARU, Sri PURWIYANTI, Roland NOWAK, Takeshi MIZUNO, Arief UDHIARTO, Djoko HARTANTO, Ryszard JABLONSKI, and Michiharu TABE

Subjects

individual dopant, pn junction, nanoscale, silicon-on-insulator, random telegraph signal, Mining engineering. Metallurgy, TN1-997

Abstract

The reduced dimensionality of present electronic devices brings along changes in the dopant distribution in the device channel, in which only a small number of dopants exist. Recent studies demonstrated that individual dopants strongly affect the electrical characteristics of nanoscale transistors. On the other hand, nanoscale pn junctions, building unit of more complex devices, have not been sufficiently studied from this viewpoint. In this work, we report several experiments that we carried out on nano-pn junctions in which the individuality of dopants is prominently observed. In electrical characteristics, we report, under various conditions, random telegraph signals (RTS) related to dopants as traps. The dynamic behavior of the depletion region of nano-pn junctions is also characterized by Kelvin probe force microscopy. DOI: http://dx.doi.org/10.5755/j01.ms.20.2.6312

Published

2014

32. Data assimilation constrains new connections and components in a complex, eukaryotic circadian clock model

Author

Alexandra Pokhilko, Sarah K Hodge, Kevin Stratford, Kirsten Knox, Kieron D Edwards, Adrian W Thomson, Takeshi Mizuno, and Andrew J Millar

Subjects

Arabidopsis thaliana, biological clocks, circadian rhythms, mathematical model, systems biology, Biology (General), QH301-705.5, Medicine (General), R5-920

Abstract

Abstract Circadian clocks generate 24‐h rhythms that are entrained by the day/night cycle. Clock circuits include several light inputs and interlocked feedback loops, with complex dynamics. Multiple biological components can contribute to each part of the circuit in higher organisms. Mechanistic models with morning, evening and central feedback loops have provided a heuristic framework for the clock in plants, but were based on transcriptional control. Here, we model observed, post‐transcriptional and post‐translational regulation and constrain many parameter values based on experimental data. The model's feedback circuit is revised and now includes PSEUDO‐RESPONSE REGULATOR 7 (PRR7) and ZEITLUPE. The revised model matches data in varying environments and mutants, and gains robustness to parameter variation. Our results suggest that the activation of important morning‐expressed genes follows their release from a night inhibitor (NI). Experiments inspired by the new model support the predicted NI function and show that the PRR5 gene contributes to the NI. The multiple PRR genes of Arabidopsis uncouple events in the late night from light‐driven responses in the day, increasing the flexibility of rhythmic regulation.

Published

2010

33. Lateral Vibration Suppression by Varying Stiffness Control in a Vertically Active Magnetic Suspension System

Author

Asief Javed, Takeshi Mizuno, Masaya Takasaki, Yuji Ishino, Masayuki Hara, and Daisuke Yamaguchi

Subjects

vertically active magnetic suspension, differential driving mode, varying stiffness, lateral vibration, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Reduction of vibration in passively supported lateral directions by varying stiffness control is discussed in a vertically active magnetic suspension system. In the target system, one pair of electromagnets is arranged in differential driving mode to actively control the vertical motion of the floator. Usually the floator is prone to vibrate in the lateral direction because it is passively supported by virtue of the edge effect of the electromagnets. In this work, such vibrations are reduced by incrementing or decrementing the currents simultaneously during vibration without changing the vertical position of the floator. This control strategy is implemented in a developed apparatus where an iron ball is suspended by differentially operated electromagnets without any mechanical contact. Experiments are carried out, and the results show the reduction of lateral vibrations without changing the vertical position of the floator.

Published

2018

34. Effect of Dehydroaltenusin-C12 Derivative, a Selective DNA Polymerase α Inhibitor, on DNA Replication in Cultured Cells

Author

Keishi Fukudome, Takeshi Mizuno, Kazunori Tsubaki, Kouji Kuramochi, Takeo Usui, Naoko Imamoto, Kengo Sakaguchi, Fumio Sugawara, Hiromi Yoshida, Yoshiyuki Mizushina, and Isoko Kuriyama

Subjects

Dehydroaltenusin-C12 (C12), DNA polymerase (DNA-directed DNA polymerase [E.C. 2.7.7.7], pol) α, Enzyme inhibitor, DNA replication, Replication fork uncoupling, Hypotonic shift, Molecule probe, Anticancer drug, Organic chemistry, QD241-441

Abstract

Dehydroaltenusin is a selective inhibitor of mammalian DNA polymerase α (pol α) from a fungus (Alternaria tennuis). We have designed, synthesized, and characterized a derivative of dehydroaltenusin conjugated with a C12-alkyl side chain (dehydroaltenusin-C12 [C12]). C12 was the strongest pol α inhibitor in vitro. We introduced C12 into NIH3T3 cells with the help of a hypotonic shift, that is, a transient exposure of cultured cells in hypotonic buffer with small molecules which can not penetrate cells. The cells that took in C12 by hypotonic shift showed cell growth inhibition. At a low concentration (5 μM), DNA replication was inhibited and several large replication protein A (RPA) foci, which is different from dUTP foci. Furthermore, when C12 was incubated with aphidicolin, RPA foci were not observed in cells. Finally, these findings suggest that C12 inhibited DNA replication through pol α inhibition, and generated single-stranded DNA, resulted in uncoupling of the leading strand and lagging strand synthesis. These findings suggest that C12 could be more interesting as a molecule probe or anticancer agent than aphidicolin. C12 might provide novel markers for the development of antiproliferative drugs.

Published

2008

35. Mass measurement using the fixed-point of a spring-mass system with a dynamic vibration absorber and an inertial-mass vibrator

Author

Tomoyuki KORIKAWA, Yuji ISHINO, Masaya TAKASAKI, and Takeshi MIZUNO

Subjects

mass measurement, dynamic vibration absorber, fixed point, phase-locked loop, space engineering, Mechanical engineering and machinery, TJ1-1570

Abstract

A mass-spring system with a dynamic vibration absorber has a fixed point in its frequency response curves. A method of measuring mass using this property was proposed. It has an advantage that mass is estimated independently of the damping in the absorber. The developed system was characterized by using a phase-looked loop to achieve the tuning condition. However, because the actuator producing the harmonic force was mounted on the base, the reaction force was transmitted to the surrounding structure. It may cause a severe vibration of the surrounding structure. Therefore, it is necessary to prevent transmission of force to the surrounding structure in measuring. In this paper, a new type of mass measurement system is proposed which uses an inertial-mass vibrator to reduce the transmitted vibration. The tuning conditions are derived for both systems with a damped absorber and with an undamped absorber. The principles of measurement are described based on a mathematical model. An experimental apparatus is designed and fabricated. The efficacy of the measurement system with an inertial mass-type vibrator is studied both analytically and experimentally.

Published

2015

36. Fabrication of non-contact carrier system using solar magnetic suspension

Author

Yuji ISHINO, Masaya TAKASAKI, and Takeshi MIZUNO

Subjects

magnetic levitation, magnetic bearing, electromagnetic actuator, renewable energy, solar energy, Mechanical engineering and machinery, TJ1-1570

Abstract

A solar-powered magnetic suspension carrier is fabricated which achieves noncontact power supply to the carrier. There are two conventional methods of supplying power to a carrier. One is through wires or contacts such as pantograph and the other is an on-board battery in the carrier. However, the contactless property is lost in the former while stations for charging the on-board battery are necessary in the latter. These problems are overcome by the proposed carrier system using solar magnetic suspension that can achieve continuous levitation. It is assumed for the system to operate indoors like inside a factory building. The generation of power by solar cells is low so that the magnetic suspension needs power saving. A zero power control system is applied to the suspension of the floator. In addition, low-power peripheral devices are also fabricated. The developed carrier system achieved a 24-hour levitation without external power supply in a bright environment.

Published

2015

37. Realization of diamagnetic levitation of column-shaped graphite

Author

Keisuke IIDA, Yoshinori NARISAWA, Yuji ISHINO, Masaya TAKASAKI, and Takeshi MIZUNO

Subjects

graphite, diamagnetism, permanent magnet, halbach array, levitation force, Mechanical engineering and machinery, TJ1-1570

Abstract

The completely passive levitation of a column-shaped graphite object is achieved. Graphite is a typical diamagnetic material. Diamagnetic materials have a property of generating repulsive force in magnetic field. Most diamagnetic levitation systems use high-oriented pyrolytic graphite (PG) sheets because sufficient force for levitation is easily obtained. In contrast, column-shaped graphites are proposed as the target of levitation in this work. Experimental apparatus for diamagnetic levitation is fabricated. The apparatus uses a two-dimensional Halbach array made of cubic neodymium magnets. The magnetic fields in the apparatus are analyzed numerically and experimentally. It is shown that the stable diamagnetic levitation of a column-shaped graphite can be achieved. The floator is fabricated by combining the pencil leads made from graphite. Then the diamagnetic forces acting on the floator are measured. In addition, the effects of anisotropy of graphite on the levitation characteristics are discussed.

Published

2015

38. Force measurement using double series magnetic suspension

Author

Takeshi MIZUNO, Daisuke SEKINE, Masaya TAKASAKI, and Yuji ISHINO

Subjects

measurement, magnetic bearing, magnetic levitation, electromagnetic actuator, precision instrument, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Double Series magnetic suspension is applied to force measurement. In a double series magnetic suspension system, two floators are suspended with a single electromagnet. The attractive force of the electromagnet directly acts on the first (upper) floator in which a permanent magnet is installed. The motion of the second (lower) floator is controlled indirectly through the attractive force of the permanent magnet. When PID control is applied to the second floator, the first floator displaces proportionally to external force acting on the second floator. Therefore, the force can be estimated for the displacement of the first floator. When the parameters are set appropriately, even small force leads to large displacement so that the proposed measurement method is suitable for noncontact measurement of micro force. An apparatus was fabricated for experimental study on the proposed measurement method. Its effectiveness was demonstrated experimentally.

Published

2014

39. Zero-power control of double parallel magnetic suspension system with parallel connected coils

Author

Yoshinori NARISAWA, Takeshi MIZUNO, Masaya TAKASAKI, and Yuji ISHINO

Subjects

magnetic suspension, zero-power control, parallel suspension, parallel connected coils, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Parallel magnetic suspension has been proposed where multiple floators are controlled with a single power amplifier. The feasibility of voltage-controlled double parallel magnetic suspension with parallel connected coils has been already demonstrated in the previous work. This study focuses on the zero-power control in a voltage-controlled double parallel suspension system with parallel connected coils. In this system, there are three methods of achieving zero-power control: feeding back the control voltage, either or the sum of the coil currents. This paper shows the conditions for the system with each zero-power controller to be controllable, and compares their performances.

Published

2014

40. Topic Classification of Key Audit Matters in Japanese Audit Reports by Zero-shot Text Classification.

Author

Nobushige Doi, Yusuke Nobuta, and Takeshi Mizuno

Published

2023

41. Intermediate Control for Stable Trajectory in a Relay-Feedback Mass Measurement System.

Author

Takeshi Mizuno, Keisuke Nishizawa, Yuji Ishino, Masaya Takasaki, and Daisuke Yamaguchi

Published

2019

42. Stabilization of Magnetic Suspension System by using First-Order-Reset Element without Derivative Feedback.

Author

Yuji Ishino, Takeshi Mizuno, Masaya Takasaki, and Daisuke Yamaguchi

Published

2019

43. Force Compensation Based on Observer for Assembly of Magnetized Components.

Author

R. Monjiyama, Takeshi Mizuno, Yuji Ishino, Masaya Takasaki, and Daisuke Yamaguchi

Published

2019

44. Realization of Vibration Absorption at Multiple Frequencies on Vacuum Chamber with Cryopump.

Author

Takeshi Mizuno, Takahito Iida, Yuji Ishino, Masaya Takasaki, Daisuke Yamaguchi, and Masayuki Hara

Published

2019

45. Proposal of Mass Estimation Regardless of Switching Position in a Relay Feedback Mass Measurement System.

Author

Taku Egawa, Takeshi Mizuno, Masaya Takasaki, Yuji Ishino, and Daisuke Yamaguchi

Published

2019

46. Vibration Suppression in the Passively-Supported Direction by Varying Bias Currents in Magnetic Suspension System.

Author

Takeshi Mizuno, Asief Javed, Yuji Ishino, Daisuke Yamaguchi, and Masaya Takasaki

Published

2018

47. Realization of zero-power control in a two-degree-of-freedom double parallel magnetic suspension system.

Author

Yoshinori Narisawa, Takeshi Mizuno, Masaya Takasaki, Yuji Ishino, Masayuki Hara, and Daisuke Yamaguchi

Published

2017

48. Resonance frequency tracking control of ultrasonic transducer for diminished haptics.

Author

Masaya Takasaki, Daisuke Yamaguchi, Masayuki Hara, Yuji Ishino, and Takeshi Mizuno

Published

2017

49. Application of phase-locked loop to mass measurement using damped dynamic vibration absorber.

Author

Takeshi Mizuno, Masaya Takasaki, and Yuji Ishino

Published

2017

50. A simple action of right index finger induces rubber hand illusion to static left hand.

Author

Masayuki Hara, Yuji Ishino, Noriaki Kanayama, Masaya Takasaki, Daisuke Yamaguchi, and Takeshi Mizuno

Published

2016