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Development and initial evaluation of wireless self-monitoring pneumatic compression sleeves for preventing deep vein thrombosis in surgical patientsCheung, William Ka Wai 05 1900 (has links)
This thesis describes the successful development and initial evaluation of a proof-of-concept wireless monitoring system for improving the effectiveness and safety of pneumatic compression therapy to help prevent deep vein thrombosis (DVT). In the development, an important objective was to make feasible the practical and commercial deployment of such improved therapy systems in future, by focusing on a cost-effective design and implementation.
Over the years, pneumatic compression has been shown to be an effective solution for the prevention of DVT. However, different problems and complications related to the use of commercial pneumatic compression de-vices that typically include automatic pressure controllers and pneumatic compression sleeves have been reported. For example, one study reported a high percentage of improperly applied or nonfunctional pneumatic compression devices in routine usage. Technical problems, non-compliance, and human error were identified as the causes behind the failed therapies. Also, it was reported that dedicated in-service instruction did not improve the proper use of the pneumatic compression controllers and sleeves. In another study, significant unanticipated variations between expected and delivered pneumatic compression therapy were reported: expected therapy delivered only an average of 77.8% of the time during the therapy, and much of the time key values related to the outcome of the therapy were found to have variations great than 10%. Specific hazards have also been reported. For example, one patient developed acute compartment syndrome after wearing a pair of pneumatic compression sleeves with faulty pressure release valves. In another case, epidural analgesia masked a malfunction resulting from a reversed connection between four-way plastic tubing of the sleeves and the controller, exposing a patient to a hazardous pressure of around 300mmHg,blocking all blood flow for a prolonged period of time.
Newer models of pneumatic compression sleeves and controllers from various manufacturers claim to improve therapy by, for example, increasing the peak blood flow velocity. However, there is no evidence in the published literature to support such claims. A published review of the literature from1970-2002 reached the conclusion that the most important factors in im-proving therapy with pneumatic compression devices, particularly during and after surgery, were the degree of conformance of delivered therapy to the prescribed therapy, patient compliance, and the appropriateness of the site of compression. The inability to monitor delivered therapy and patient compliance remains a problem in efforts to improve pneumatic compression therapy.
The above-described problems were addressed in the successful development of the innovative prototype described in this thesis. This wireless monitoring system should improve the effectiveness and safety of pneumatic compression therapy. Also, innovative aspects of the system design allow for cost-effective integration into existing commercial controllers and sleeves. For example, an innovative and potentially patentable usage and reprocess indicator was developed for pneumatic compression sleeves to significantly improve their safety and to reduce their cost of use per patient.
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Wireless Monitoring of Railway EmbankmentsDantal, Vishal S. 2009 December 1900 (has links)
Landslides are one of the most dangerous geological hazards. In the United
States, landslides cause a damage of $ 3.5 billion and kill 25 to 50 people annually.
Shallow landslides occurring near any transportation facilities (railways and highways)
can cause economic loss and disturbance of services which lead to indirect economic
loss. It also increases the maintenance cost of those facilities. Hence, facilities located
near a shallow landslide prone area should be monitored so as to avoid any catastrophic
damages. Soil moisture and movement of the soil mass are prime indicators of potential
shallow slide movements.
This assessment of wireless instruments considers a variety of devices ranging
from devices for monitoring tilt and moisture at specific points in the soil mass to ground
penetrating radar (GPR), which can give indications of moisture accumulation in soils
over a wide spatial extent. For this assessment study, a low cost MEMS accelerometer
was selected for measuring tilts and motions. And EC type soil moisture sensor was
selected to measure soil moisture content of embankments. The instrumentation of railway embankments works effectively and cheaply when a suspected problem area has
already been identified and monitoring is needed over a limited spatial extent. This
makes the monitoring system highly localized which often fails to cover potentially new
failure prone areas. It is not feasible to use this approach to monitor soil conditions along
the entire alignment of the railway. Therefore, another approach, GPR, is defined and
explained in this study. GPR measures the dielectric constant value for any given
material including soils. In soils, the dielectric constant value depends on the volumetric
amount of water content present in a soil. Due to moisture infiltration, there is a
reduction in suction value on embankment which indicates a decrease in shear strength
of slope. Therefore, a correlation between suction and dielectric constant value is
formulated in this study using Complex Refractive index model/Time propagation
(CRIM/TP) model for soils. To validate this theoretical correlation, a laboratory study
was conducted on pure kaolinite and on normal soil. For pure kaolinite this correlation
proves beneficial while, for other type of soil, the correlation was off due to the
limitations in filter paper test to measure suction below 2.5pF.
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Development and initial evaluation of wireless self-monitoring pneumatic compression sleeves for preventing deep vein thrombosis in surgical patientsCheung, William Ka Wai 05 1900 (has links)
This thesis describes the successful development and initial evaluation of a proof-of-concept wireless monitoring system for improving the effectiveness and safety of pneumatic compression therapy to help prevent deep vein thrombosis (DVT). In the development, an important objective was to make feasible the practical and commercial deployment of such improved therapy systems in future, by focusing on a cost-effective design and implementation.
Over the years, pneumatic compression has been shown to be an effective solution for the prevention of DVT. However, different problems and complications related to the use of commercial pneumatic compression de-vices that typically include automatic pressure controllers and pneumatic compression sleeves have been reported. For example, one study reported a high percentage of improperly applied or nonfunctional pneumatic compression devices in routine usage. Technical problems, non-compliance, and human error were identified as the causes behind the failed therapies. Also, it was reported that dedicated in-service instruction did not improve the proper use of the pneumatic compression controllers and sleeves. In another study, significant unanticipated variations between expected and delivered pneumatic compression therapy were reported: expected therapy delivered only an average of 77.8% of the time during the therapy, and much of the time key values related to the outcome of the therapy were found to have variations great than 10%. Specific hazards have also been reported. For example, one patient developed acute compartment syndrome after wearing a pair of pneumatic compression sleeves with faulty pressure release valves. In another case, epidural analgesia masked a malfunction resulting from a reversed connection between four-way plastic tubing of the sleeves and the controller, exposing a patient to a hazardous pressure of around 300mmHg,blocking all blood flow for a prolonged period of time.
Newer models of pneumatic compression sleeves and controllers from various manufacturers claim to improve therapy by, for example, increasing the peak blood flow velocity. However, there is no evidence in the published literature to support such claims. A published review of the literature from1970-2002 reached the conclusion that the most important factors in im-proving therapy with pneumatic compression devices, particularly during and after surgery, were the degree of conformance of delivered therapy to the prescribed therapy, patient compliance, and the appropriateness of the site of compression. The inability to monitor delivered therapy and patient compliance remains a problem in efforts to improve pneumatic compression therapy.
The above-described problems were addressed in the successful development of the innovative prototype described in this thesis. This wireless monitoring system should improve the effectiveness and safety of pneumatic compression therapy. Also, innovative aspects of the system design allow for cost-effective integration into existing commercial controllers and sleeves. For example, an innovative and potentially patentable usage and reprocess indicator was developed for pneumatic compression sleeves to significantly improve their safety and to reduce their cost of use per patient.
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Development and initial evaluation of wireless self-monitoring pneumatic compression sleeves for preventing deep vein thrombosis in surgical patientsCheung, William Ka Wai 05 1900 (has links)
This thesis describes the successful development and initial evaluation of a proof-of-concept wireless monitoring system for improving the effectiveness and safety of pneumatic compression therapy to help prevent deep vein thrombosis (DVT). In the development, an important objective was to make feasible the practical and commercial deployment of such improved therapy systems in future, by focusing on a cost-effective design and implementation.
Over the years, pneumatic compression has been shown to be an effective solution for the prevention of DVT. However, different problems and complications related to the use of commercial pneumatic compression de-vices that typically include automatic pressure controllers and pneumatic compression sleeves have been reported. For example, one study reported a high percentage of improperly applied or nonfunctional pneumatic compression devices in routine usage. Technical problems, non-compliance, and human error were identified as the causes behind the failed therapies. Also, it was reported that dedicated in-service instruction did not improve the proper use of the pneumatic compression controllers and sleeves. In another study, significant unanticipated variations between expected and delivered pneumatic compression therapy were reported: expected therapy delivered only an average of 77.8% of the time during the therapy, and much of the time key values related to the outcome of the therapy were found to have variations great than 10%. Specific hazards have also been reported. For example, one patient developed acute compartment syndrome after wearing a pair of pneumatic compression sleeves with faulty pressure release valves. In another case, epidural analgesia masked a malfunction resulting from a reversed connection between four-way plastic tubing of the sleeves and the controller, exposing a patient to a hazardous pressure of around 300mmHg,blocking all blood flow for a prolonged period of time.
Newer models of pneumatic compression sleeves and controllers from various manufacturers claim to improve therapy by, for example, increasing the peak blood flow velocity. However, there is no evidence in the published literature to support such claims. A published review of the literature from1970-2002 reached the conclusion that the most important factors in im-proving therapy with pneumatic compression devices, particularly during and after surgery, were the degree of conformance of delivered therapy to the prescribed therapy, patient compliance, and the appropriateness of the site of compression. The inability to monitor delivered therapy and patient compliance remains a problem in efforts to improve pneumatic compression therapy.
The above-described problems were addressed in the successful development of the innovative prototype described in this thesis. This wireless monitoring system should improve the effectiveness and safety of pneumatic compression therapy. Also, innovative aspects of the system design allow for cost-effective integration into existing commercial controllers and sleeves. For example, an innovative and potentially patentable usage and reprocess indicator was developed for pneumatic compression sleeves to significantly improve their safety and to reduce their cost of use per patient. / Applied Science, Faculty of / Electrical and Computer Engineering, Department of / Graduate
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Wireless physiological monitoring system for psychiatric patientsRademeyer, A. J. 12 1900 (has links)
Thesis (MScEng (Mechanical and Mechatronic Engineering))--Stellenbosch University, 2008. / This thesis is concerned with the development and testing of a non-invasive device that is
unassailable, and can be placed on an aggressive psychiatric patient to monitor the vital
signs of this patient. Two devices, a glove measuring oxygen saturation and another on
the dorsal part (back) of the patient measuring heart rate via electrocardiography (ECG),
skin temperature and respiratory rate were designed and implemented. The data is
transmitted using wireless technology. Both devices connect to one central monitoring
station using two separate Bluetooth connections ensuring a total wireless setup. All the
hardware and software to measure these variables have been designed and implemented.
A Matlab graphical user interface (GUI) was developed for signal processing and
monitoring of the vital signs of the psychiatric patient. Detection algorithms were
implemented to detect ECG arrhythmias such as premature ventricular contraction and
atrial fibrillation. The prototype was manufactured and tested in a laboratory setting on
five volunteers. Satisfactory test results were obtained and the primary objectives of the
thesis were fulfilled
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マシニングセンタを用いたスレッドミルのヘリカル補間運動に基づく雌ねじ切り加工法に関する研究 / マシニング センタ オ モチイタ スレッド ミル ノ ヘリカル ホカン ウンドウ ニ モトズク メネジキリ カコウホウ ニカンスル ケンキュウ松井 翔太, Shota Matsui 22 March 2021 (has links)
本報は,雌ねじ切り工具であるスレッドミルを使用した雌ねじ切り加工を研究対象としている.スレッドミル加工の特性やねじ精度について,切削力や加工温度を計測し解析することで検討をおこないその結果を記載している.計測には無線ホルダやサーボドライブユニット等の最新のIoT技術も使用することで,近年増加傾向にあるIoT技術の適応も試みた. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University
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Piezoelectric Energy Harvesting for Powering Wireless Monitoring SystemsQian, Feng 26 June 2020 (has links)
The urgent need for a clean and sustainable power supply for wireless sensor nodes and low-power electronics in various monitoring systems and the Internet of Things has led to an explosion of research in substitute energy technologies. Traditional batteries are still the most widely used power source for these applications currently but have been blamed for chemical pollution, high maintenance cost, bulky volume, and limited energy capacity. Ambient energy in different forms such as vibration, movement, heat, wind, and waves otherwise wasted can be converted into usable electricity using proper transduction mechanisms to power sensors and low-power devices or charge rechargeable batteries. This dissertation focuses on the design, modeling, optimization, prototype, and testing of novel piezoelectric energy harvesters for extracting energy from human walking, bio-inspired bi-stable motion, and torsional vibration as an alternative power supply for wireless monitoring systems.
To provide a sustainable power supply for health care monitoring systems, a piezoelectric footwear harvester is developed and embedded inside a shoe heel for scavenging energy from human walking. The harvester comprises of multiple 33-mode piezoelectric stacks within single-stage force amplification frames sandwiched between two heel-shaped aluminum plates taking and reallocating the dynamic force at the heel. The single-stage force amplification frame is designed and optimized to transmit, redirect, and amplify the heel-strike force to the inner piezoelectric stack. An analytical model is developed and validated to predict precisely the electromechanical coupling behavior of the harvester. A symmetric finite element model is established to facilitate the mesh of the transducer unit based on a material equivalent model that simplifies the multilayered piezoelectric stack into a bulk. The symmetric FE model is experimentally validated and used for parametric analysis of the single-stage force amplification frame for a large force amplification factor and power output. The results show that an average power output of 9.3 mW/shoe and a peak power output of 84.8 mW are experimentally achieved at the walking speed of 3.0 mph (4.8 km/h). To further improve the power output, a two-stage force amplification compliant mechanism is designed and incorporated into the footwear energy harvester, which could amplify the dynamic force at the heel twice before applied to the inner piezoelectric stacks. An average power of 34.3 mW and a peak power of 110.2 mW were obtained under the dynamic force with the amplitude of 500 N and frequency of 3 Hz. A comparison study demonstrated that the proposed two-stage piezoelectric harvester has a much larger power output than the state-of-the-art results in the literature.
A novel bi-stable piezoelectric energy harvester inspired by the rapid shape transition of the Venus flytrap leaves is proposed, modeled and experimentally tested for the purpose of energy harvesting from broadband frequency vibrations. The harvester consists of a piezoelectric macro fiber composite (MFC) transducer, a tip mass, and two sub-beams with bending and twisting deformations created by in-plane pre-displacement constraints using rigid tip-mass blocks. Different from traditional ways to realize bi-stability using nonlinear magnetic forces or residual stress in laminate composites, the proposed bio-inspired bi-stable piezoelectric energy harvester takes advantage of the mutual self-constraint at the free ends of the two cantilever sub-beams with a pre-displacement. This mutual pre-displacement constraint bi-directionally curves the two sub-beams in two directions inducing higher mechanical potential energy. The nonlinear dynamics of the bio-inspired bi-stable piezoelectric energy harvester is investigated under sweeping frequency and harmonic excitations. The results show that the sub-beams of the harvester experience local vibrations, including broadband frequency components during the snap-through, which is desirable for large power output. An average power output of 0.193 mW for a load resistance of 8.2 kΩ is harvested at the excitation frequency of 10 Hz and amplitude of 4.0 g.
Torsional vibration widely exists in mechanical engineering but has not yet been well exploited for energy harvesting to provide a sustainable power supply for structural health monitoring systems. A torsional vibration energy harvesting system comprised of a shaft and a shear mode piezoelectric transducer is developed in this dissertation to look into the feasibility of harvesting energy from oil drilling shaft for powering downhole sensors. A theoretical model of the torsional vibration piezoelectric energy harvester is derived and experimentally verified to be capable of characterizing the electromechanical coupling system and predicting the electrical responses. The position of the piezoelectric transducer on the surface of the shaft is parameterized by two variables that are optimized to maximize the power output. Approximate expressions of the voltage and power are derived by simplifying the theoretical model, which gives predictions in good agreement with analytical solutions. Based on the derived approximate expression, physical interpretations of the implicit relationship between the power output and the position parameters of the piezoelectric transducer are given. / Doctor of Philosophy / Wireless monitoring systems with embedded wireless sensor nodes have been widely applied in human health care, structural health monitoring, home security, environment assessment, and wild animal tracking. One distinctive advantage of wireless monitoring systems is to provide unremitting, wireless monitoring of interesting parameters, and data transmission for timely decision making. However, most of these systems are powered by traditional batteries with finite energy capacity, which need periodic replacement or recharge, resulting in high maintenance costs, interruption of service, and potential environmental pollution. On the other hand, abundant energy in different forms such as solar, wind, heat, and vibrations, diffusely exists in ambient environments surrounding wireless monitoring systems which would be otherwise wasted could be converted into usable electricity by proper energy transduction mechanisms.
Energy harvesting, also referred to as energy scavenging and energy conversion, is a technology that uses different energy transduction mechanisms, including electromagnetic, photovoltaic, piezoelectric, electrostatic, triboelectric, and thermoelectric, to convert ambient energy into electricity. Compared with traditional batteries, energy harvesting could provide a continuous and sustainable power supply or directly recharge storage devices like batteries and capacitors without interrupting operation. Among these energy transduction mechanisms, piezoelectric materials have been extensively explored for small-size and low-power generation due to their merits of easy shaping, high energy density, flexible design, and low maintenance cost. Piezoelectric transducers convert mechanical energy induced by dynamic strain into electrical charges through the piezoelectric effect.
This dissertation presents novel piezoelectric energy harvesters, including design, modeling, prototyping, and experimental tests for energy harvesting from human walking, broadband bi-stable nonlinear vibrations, and torsional vibrations for powering wireless monitoring systems. A piezoelectric footwear energy harvester is developed and embedded inside a shoe heel for scavenging energy from heel striking during human walking to provide a power supply for wearable sensors embedded in health monitoring systems. The footwear energy harvester consists of multiple piezoelectric stacks, force amplifiers, and two heel-shaped metal plates taking dynamic forces at the heel. The force amplifiers are designed and optimized to redirect and amplify the dynamic force transferred from the heel-shaped plates and then applied to the inner piezoelectric stacks for large power output. An analytical model and a finite model were developed to simulate the electromechanical responses of the harvester. The footwear harvester was tested on a treadmill under different walking speeds to validate the numerical models and evaluate the energy generation performance. An average power output of 9.3 mW/shoe and a peak power output of 84.8 mW are experimentally achieved at the walking speed of 3.0 mph (4.8 km/h). A two-stage force amplifier is designed later to improve the power output further. The dynamic force at the heel is amplified twice by the two-stage force amplifiers before applied to the piezoelectric stacks. An average power output of 34.3 mW and a peak power output of 110.2 mW were obtained from the harvester with the two-stage force amplifiers.
A bio-inspired bi-stable piezoelectric energy harvester is designed, prototyped, and tested to harvest energy from broadband vibrations induced by animal motions and fluid flowing for the potential applications of self-powered fish telemetry tags and bird tags. The harvester consists of a piezoelectric macro fiber composite (MFC) transducer, a tip mass, and two sub-beams constrained at the free ends by in-plane pre-displacement, which bends and twists the two sub-beams and consequently creates curvatures in both length and width directions. The bi-direction curvature design makes the cantilever beam have two stable states and one unstable state, which is inspired by the Venus flytrap that could rapidly change its leaves from the open state to the close state to trap agile insects. This rapid shape transition of the Venus flytrap, similar to the vibration of the harvester from one stable state to the other, is accompanied by a large energy release that could be harvested. Detailed design steps and principles are introduced, and a prototype is fabricated to demonstrate and validate the concept. The energy harvesting performance of the harvester is evaluated at different excitation levels.
Finally, a piezoelectric energy harvester is developed, analytically modeled, and validated for harvesting energy from the rotation of an oil drilling shaft to seek a continuous power supply for downhole sensors in oil drilling monitoring systems. The position of the piezoelectric transducer on the surface of the shaft is parameterized by two variables that are optimized to obtain the maximum power output. Approximate expressions of voltage and power of the torsional vibration piezoelectric energy harvester are derived from the theoretical model. The implicit relationship between the power output and the two position parameters of the transducer is revealed and physically interpreted based on the approximate power expression. Those findings offer a good reference for the practical design of the torsional vibration energy harvesting system.
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IEEE 802.11b MAC layer's influence on VoIP quality parameters : Measurements and AnalysisMartín Severiano, Juan Carlos January 2004 (has links)
Real-time voice measurements were performed to assess whether there are significant problems with 802.11b wireless networks regarding real-time voice communication. We present an analysis of how the 802.11b MAC protocol and diverse environmental conditions affect the quality of real-time voice in terms of loss, delay, and jitter. We also reveal practical issues of wireless monitoring with passive sniffers for this type of analysis. The results obtained in our measurements show that in the majority of the experiments the quality was good, but under some circumstances the requirements for an acceptable voice communication were not met. / Realtidsröstmätningar gjordes för att testa om det finns problem med 802.11b trådlösa nätverk beträffande realtidsröstkommunikation. En analys presenteras av hur 802.11b MACs protokoll och olika tillstånd i omgivningen påverkar kvaliteten på realtidsrösten i form av förluster, fördröjningar och jitter. Även praktiska angelägenheter om trådlös övervakning med passiva sniffers visas. De erhållna resultaten visar att i en majoritet av fallen var kvaliteten acceptabel, men under vissa förhållanden blev inte kraven för röstkommunikation uppfyllda.
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[pt] ANÁLISE DA SENSIBILIDADE À DEFORMAÇÃO DE UM DISPOSITIVO RESSONADOR DE ONDA DE SUPERFÍCIE / [en] STRAIN SENSITIVITY ANALISYS OF A SURFACE ACOUSTIC WAVE RESONATOR DEVICE22 March 2018 (has links)
[pt] Os sensores de deformação convencionais, por exemplo, os strain gages resistivos e ópticos, consagrados pelo mercado, são empregados em diferentes ambientes e estruturas, oferecendo um nível de flexibilidade que permite sua integração a vários tipos de sistemas de medição. No entanto, requerem uma fonte de energia elétrica local ou não podem funcionar sem cabos, limitando o seu uso em alguns cenários, como em partes móveis de máquinas. Os dispositivos SAW (Surface Acoustic Wave) podem ser usados como sensores de deformação piezoelétricos, pois possuem sensibilidade à deformação e podem operar de forma passiva por meio de antenas, podendo ser integrados a sistemas de monitoramento sem fio. Seu funcionamento é baseado em ondas de superfície geradas em um meio piezoelétrico. O estado de tensão na superfície do meio altera as características dessas ondas e induz mudanças na frequência de operação. O presente trabalho analisou a sensibilidade à deformação de dispositivos SAW ressonadores feitos de quartzo ST-X com frequência central de 433,92 MHz colados com diferentes adesivos, e testou sua operação como sensores passivos sem fio. A metodologia incluiu testes de tração não destrutivos em diferentes temperaturas e também simulações com elementos finitos. Os resultados experimentais mostraram relação linear entre a variação de frequência dos ressonadores e as deformações aplicadas, concordando com a literatura. A interrogação sem fio foi bem sucedida, confirmando o grande potencial dessa tecnologia. Os resultados numéricos, combinados a um modelo teórico, foram próximos aos experimentais, validando o modelo numérico. / [en] The conventional strain sensors, e.g., resistive and optical strain gages, established in the market, are deployed in different environments and structures, providing the flexibility of integration with different measurement systems. However, they require a local energy source to work or cables, limiting their use in some scenarios such as moving parts of machines. The SAW (Surface Acoustic Wave) devices can be used as piezoelectric strain sensors since they have sensitivity to strain, can operate passively by antennas and can be integrated to wireless monitoring systems. Its working principle is based on surface acoustic waves generated on piezolectric medium. The stress state of the medium changes the characteristics of these waves and induces changes in the operating frequency. The present work analyzed the strain sensitivity of SAW resonators made of ST-X cut quartz operating at a central frequency of 433,92 MHz, bonded with different adhesives, and tested their operation as passive wirelesss sensors. The methodology included non-destructive tensile testing at different temperature, and also finite elements simulations. The experimental results showed linear relation between the frequency change and the applied strain, agreeing with the literature. The wireless interrogations was successful, confirming the great potential of this technology. The numerical results, combined to a theoretical model, matched well the experiments, validating the model.
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ワイヤレス多機能無線ホルダーシステムを用いた加工現象のモニタと診断に関する研究 / ワイヤレス タキノウ ムセン ホルダー システム オ モチイタ カコウ ゲンショウ ノ モニタ ト シンダン ニカンスル ケンキュウ松田 亮, Ryo Matsuda 22 March 2019 (has links)
近年,IoTに基づく「つながる工場」に関する技術開発が着目され,日本の次世代の製造業を支えるために,新しい研究開発が求められている.特に機械加工の現場では,異常検知や適応制御のために加工現象を精確かつリアルタイムにモニタできる技術が必要とされている.そこで,マシニングセンタなどの工作機械において,回転工具の加工中に多チャンネルで各種の物理量を切削点近傍にてモニタ可能な無線多機能ホルダを開発し,様々な工具,加工方法を対象にその有効性を示した. / Currently, a smart monitoring technology has been attracting particular attention in the factory automation fields regarding the Internet of things (IoT). Particularly in the machining site, the technology of monitoring the processing phenomenon in precision and real-time is required for abnormality detection or adaptive control. Then, we developed a novel tool holder equipped with a wireless communication function to monitor the tool temperature and vibrating accelerations near the cutting point during a tool rotating operation, and we showed effectiveness for various tools and processing method. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University
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