Определение аэродинамической силы в закрытом боксе стенда для. Из-за диких свиней в атмосферу попадает 4,9 миллиона метрических тонн углекислого газа, что эквивалентно выбросам 1,1 миллиона машин.
В Феврале Заговорили Летающие Свиньи и Основали Собственную Авиакомпанию!
Конструктор назвал свой проект Hamborghini «Ветчиргини» , обыграв слово ham ветчина и марку автомобилей Lamborghini. Главной особенностью конструкции стали мощный мотор, который позволяет свинье развивать скорость до 32 километров в час, а также встроенный в её голову ИК-датчик. Когда сенсор определяет, что перед ним находится напечатанная на 3D-принтере морковка, Ветчиргини начинает движение. В Minecraft свиньёй можно управлять аналогичным образом, используя удочку с морковью.
С конца 90-х годов в авиации накопилось достаточно данных о реальном поведении самолетов, чтобы понять недостатки имеющегося метода оценки подъемной силы с помощью формулы Жуковского. Она позволяет рассчитать циркуляцию вихревых потоков вокруг крыла в двух измерениях, но не подходит для описания наблюдаемых продольных трехмерных вихрей. Их можно наблюдать на авиашоу во время исполнения пилотажных фигур. Отдельное научное направление — компьютерная вихревая аэродинамика — занимается анализом параметров вихревых турбулентных потоков и поиском зависимостей для математического моделирования. Команда исследователей из Эдинбургского университета решила применить новые знания для моделирования полета семянки одуванчика, поведение которой в воздухе оставляло немало вопросов.
However, for some birds, they land by folding their wings as they perch instead, creating a sweeping motion as they decelerate. To uncover the mystery behind these differences in motion, a team of researchers in the UCF Department of Mechanical and Aerospace Engineering studied the aerodynamics of bird perching maneuvers and their implications for aircraft design. So, a perching maneuver with swept-wing configuration can be an option where runway distance is an issue. A rectangular plate was used to mimic a straight wing while a tapered plate was used to mimic a folded wing.
However, viscous effects become more important in structuring flow and thus cannot be ignored.
Due to these viscous effects, the principles underlying aerodynamic force production may differ in small vs large insects. For tiny insects, small perturbations in the fluid may be more rapidly dissipated due to viscous resistance to fluid motion. However, for larger insects operating at higher Reynolds numbers, small perturbations in the flow field accumulate with time and may ultimately result in stronger unsteadiness of the surrounding flows. Even with the accurate knowledge of the smallest perturbations, such situations are impossible to predict analytically because there may be several possible solutions to the flow equations. In such cases,strict static and dynamic initial and boundary conditions must be identified to reduce the number of solutions to a few meaningful possibilities.
Analytical models of insect flight The experimental and theoretical challenges mentioned in the previous sections constrained early models of insect flight to analysis of far-field wakes rather than the fluid phenomena in the immediate vicinity of the wing. Although such far-field models could not be used to calculate the instantaneous forces on airfoils, they offered some hope of characterizing average forces as well as power requirements. By this method, the mean lift required to hover may be estimated by equating the rate of change of momentum flux within the downward jet with the weight of the insect and thus calculating the circulation required in the wake to maintain this force balance. A detailed description of these theories appears in Rayner 1979a , b and Ellington 1984e and is beyond the scope of this review, which will focus instead on near-field models. Despite the caveats presented in the last section, a few researchers have been able to construct analytical near-field models for the aerodynamics of insect flight with some degree of success.
Notable among these are the models of Lighthill 1973 for the Weis-Fogh mechanism of lift generation also called clap-and-fling , first proposed to explain the high lift generated in the small chalcid wasp Encarsia formosa, and that of Savage et al. Although both these models were fundamentally two dimensional and inviscid albeit with some adjustments to include viscous effects , they were able to capture some crucial aspects of the underlying aerodynamic mechanisms. Similarly,the model of Savage et al. This method takes into account the spatial along the span and temporal changes in induced velocity and estimates corrections in the circulation due to the wake. The more recent analytical models e.
Zbikowski, 2002 ; Minotti, 2002 have been able to incorporate the basic phenomenology of the fluid dynamics underlying flapping flight in a more rigorous fashion, as well as take advantage of a fuller database of forces and kinematics Sane and Dickinson,2001. Computational fluid dynamics CFD With recent advances in computational methods, many researchers have begun exploring numerical methods to resolve the insect flight problem, with varying degrees of success Smith et al. Although ultimately these techniques are more rigorous than simplified analytical solutions, they require large computational resources and are not as easily applied to large comparative data sets. Furthermore, CFD simulations rely critically on empirical data both for validation and relevant kinematic input. Nevertheless, several collaborations have recently emerged that have led to some exciting CFD models of insect flight.
One such approach involved modeling the flight of the hawkmoth Manduca sexta using the unsteady aerodynamic panel method Smith et al. In addition to confirming the smoke streak patterns observed on both real and dynamically scaled model insects Ellington et al. More recently,computational approaches have been used to model Drosophila flight for which force records exist based on a dynamically scaled model Dickinson et al. Although roughly matching experimental results, these methods have added a wealth of qualitative detail to the empirical measurements Ramamurti and Sandberg, 2002 and even provided alternative explanations for experimental results Sun and Tang, 2002 ; see also section on wing—wake interactions. Despite the importance of 3-D effects, comparisons of experiments and simulations in 2-D have also provided important insight.
Two-dimensional CFD models have also been useful in addressing feasibility issues. For example, Wang 2000 demonstrated that the force dynamics of 2-D wings, although not stabilized by 3-D effects, might still be sufficient to explain the enhanced lift coefficients measured in insects. Quasi-steady modeling of insect flight In the hope of finding approximate analytical solutions to the insect flight problem, scientists have developed simplified models based on the quasi-steady approximations. According to the quasi-steady assumption, the instantaneous aerodynamic forces on a flapping wing are equal to the forces during steady motion of the wing at an identical instantaneous velocity and angle of attack Ellington,1984a. It is therefore possible to divide any dynamic kinematic pattern into a series of static positions, measure or calculate the force for each and thus reconstruct the time history of force generation.
By this method, any time dependence of the aerodynamic forces arises from time dependence of the kinematics but not that of the fluid flow itself. If such models are accurate, then it would be possible to use a relatively simple set of equations to calculate aerodynamic forces on insect wings based solely on knowledge of their kinematics. Although quasi-steady models had been used with limited success in the past Osborne, 1950 ; Jensen, 1956 , they generally appeared insufficient to account for the necessary mean lift in cases where the average flight force data are available. Conversely, if the maximum force calculated from the model was greater than or equal to the mean forces required for hovering,then the quasi-steady model cannot be discounted. Based on a wide survey of data available at the time, he convincingly argued that in most cases the existing quasi-steady theory fell short of calculating even the required average lift for hovering, and a substantial revision of the quasi-steady theory was therefore necessary Ellington,1984a.
He further proposed that the quasi-steady theory must be revised to include wing rotation in addition to flapping translation, as well as the many unsteady mechanisms that might operate. Since the Ellington review, several researchers have provided more data to support the insufficiency of the quasi-steady model Ennos, 1989a ; Zanker and Gotz, 1990 ; Dudley, 1991. These developments have spurred the search for specific unsteady mechanisms to explain the aerodynamic forces on insect wings. Physical modeling of insect flight Given the difficulties in directly studying insects or making theoretical calculations of their flight aerodynamics, many researchers have used mechanical models to study insect flight. These various mechanisms are discussed in the following section.
Unsteady mechanisms in insect flight Wagner effect When an inclined wing starts impulsively from rest, the circulation around it does not immediately attain its steady-state value Walker, 1931. Instead, the circulation rises slowly to the steady-state estimate Fig. This delay in reaching the steady-state values may result from a combination of two phenomena. First, there is inherent latency in the viscous action on the stagnation point and thus a finite time before the establishment of Kutta condition.
Aerodynamics of perching birds could inform aircraft design
В удивительной серии событий, произошедших в феврале этого года, свидетели утверждают, что видели летающих свиней. Тульский агрокомплекс "Лазаревское" разработал ИИ-систему, которая с помощью видеокамер взвешивает свиней и определяет их уровень здоровья. NRC-кормление свиней.
Aerodynamic Innovation in Motocross
| Свиньи летают! Но только очень низко... | Experiments and simulations suggest that the airplane-like wing position adopted by some birds when they land helps to increase lift. |
| В Феврале Заговорили Летающие Свиньи и Основали Собственную Авиакомпанию! | ГГлавные Новости | Дзен | Война свиней у корыта», – написал Медведев в своём телеграм-канале. |
| Дикие свиньи оказались опаснее для климата, чем миллион авто - Погода | и аэродинамика. микромеханика. |
Голландские пищевики обратили внимание на аэродинамику
Оптимизировать аэродинамику здоровенной фуры сложно, да и начальство типичной автокомпании не любит слишком революционных решений. Свинья закрывает за собой дверь, когда идет на горшок. Comments on: Suspension, grip and aerodynamics.
Почему свиньи не летают?
Что именно демонстрируется на диаграммах — не уточняется, но выглядят они как какой-то прикол, хоть таковым и не являются. Перед вами примеры причудливых иллюстраций, которые точно имеют смысл.
Именно столько, по заводским характеристикам, потребляет гибридный Pacifica нового поколения. Даже если в реальной жизни эта цифра будет в полтора раза выше, экономичность новинки впечатляет. С пустым бензобаком Pacifica Hybrid способен проехать до 53 км на электротяге. При этом 7,5 тысячи долларов государство вернет вам за то, что вы купили гибрид.
Птиц очень привлекают эти места, где они находят пищу, но власти постоянно борются за то, чтобы их не было.
Только в прошлом году в «Схипхоле» было зарегистрировано более 150 столкновений самолетов с птицами. По словам ответственного за флору и фауну в районе аэропорта, за те несколько недель, что животные появились там, столкновений с птицами не зафиксировано.
Furthermore, when observed, the importance of the clap must always be weighed against a simpler alternative but not mutually exclusive hypothesis that the animal is simply attempting to maximize stroke amplitude, which can significantly enhance force generation. Animals appear to increase lift by gradually expanding stroke angle until the wings either touch or reach some other morphological limit with the body. Thus, an insect exhibiting a clap may be attempting to maximize stroke amplitude. Furthermore, if it is indeed true that the Wagner effect only negligibly influences aerodynamic forces on insect wings, the classically described benefits of clap-and-fling may be less pronounced than previously thought. Resolution of these issues awaits a more detailed study of flows and forces during clap-and-fling. Delayed stall and the leading edge vortex As the wing increases its angle of attack, the fluid stream going over the wing separates as it crosses the leading edge but reattaches before it reaches the trailing edge.
In such cases, a leading edge vortex occupies the separation zone above the wing. Because the flow reattaches, the fluid continues to flow smoothly from the trailing edge and the Kutta condition is maintained. In this case, because the wing translates at a high angle of attack, a greater downward momentum is imparted to the fluid, resulting in substantial enhancement of lift. Experimental evidence and computational studies over the past 10 years have identified the leading edge vortex as the single most important feature of the flows created by insect wings and thus the forces they create. Polhamus 1971 described a simple way to account for the enhancement of lift by a leading edge vortex that allows for an easy quantitative analysis. For blunt airfoils, air moves sharply around the leading edge, thus causing a leading edge suction force parallel to the wing chord. This extra force component adds to the potential force component which acts normal to the wing plane , causing the resultant force to be perpendicular to the ambient flow velocity, i. At low angles of attack, this small forward rotation due to leading edge suction means that conventional airfoils better approximate the zero drag prediction of potential theory Kuethe and Chow,1998.
However, for airfoils with sharper leading edge, flow separates at the leading edge, leading to the formation of a leading edge vortex. In this case, an analogous suction force develops not parallel but normal to the plane of the wing, thus adding to the potential force and consequently enhancing the lift component. Note that in this case, the resultant force is perpendicular to the plane of the wing and not to ambient velocity. Thus, drag is also increased Fig. A Flow around a blunt wing. The sharp diversion of flow around the leading edge results in a leading-edge suction force dark blue arrow , causing the resultant force vector light blue arrow to tilt towards the leading edge and perpendicular to free stream. B Flow around a thin airfoil. The presence of a leading edge vortex causes a diversion of flow analogous to the flow around the blunt leading edge in A but in a direction normal to the surface of the airfoil.
This results in an enhancement of the force normal to the wing section. For 2-D motion, if the wing continues to translate at high angles of attack, the leading edge vortex grows in size until flow reattachment is no longer possible. The Kutta condition breaks down as vorticity forms at the trailing edge creating a trailing edge vortex as the leading edge vortex sheds into the wake. At this point, the wing is not as effective at imparting a steady downward momentum to the fluid. As a result, there is a drop in lift,and the wing is said to have stalled. The first evidence for delayed stall in insect flight was by provided by Maxworthy 1979 , who visualized the leading edge vortex on the model of a flinging wing. However, delayed stall was first identified experimentally on model aircraft wings as an augmentation in lift at the onset of motion at angles of attack above steady-state stall Walker, 1931. As the trailing edge vortex detaches and is shed into the wake, a new leading vortex forms.
The forces generated by the moving plate oscillate in accordance to the alternating pattern of vortex shedding. Although both lift and drag are greatest during phases when a leading edge vortex is present,forces are never as high as during the initial cycle. View large Download slide A comparison of 2-D linear translation vs 3-D flapping translation. A 2-D linear translation. As an airfoil begins motion from rest, it generates a leading and trailing edge vortex. During translation, the trailing edge vortex is shed, leading to the growth of the leading edge vortex, which also sheds as the airfoil continues to translate. This motion leads to an alternate vortex shedding pattern from the leading and trailing edges, called the von Karman vortex street. This leads to a time dependence of the net aerodynamic forces blue arrows measured on the airfoil.
B 3-D flapping translation. As in A, when an airfoil undergoing flapping translation starts from rest, it generates a leading and trailing edge vortex. However, as the motion progresses, the leading edge vortex attains a constant size and does not grow any further. Because no new vorticity is generated at the leading edge, there is no additional vorticity generated at the trailing edge and the airfoil obeys the Kutta condition. After establishment of the Kutta condition, the measured net aerodynamic forces blue arrows stay stable over a substantial period during translation and do not show time dependence. Ultimately, however, the net downward momentum imparted by the airfoil to the fluid causes a downwash that slightly lowers the constant value of the net aerodynamic force on a steadily revolving wing. The leading edge vortex may be especially important because insects flap their wings at high angles of attack.
Aerodynamics of Perching Birds Could Inform Aircraft Design
(2010) Recent progress in flapping wing aerodynamics and aeroelasticity. Аэродинамика – это основной фактор, оказывающий огромное влияние на расход топлива. (2010) Recent progress in flapping wing aerodynamics and aeroelasticity. Один профессор аэродинамики, участвовавший в «гусиной дискуссии» в интернете обосновал поведение птицы и нарисовал схему ее движения в воздушных потоках. Неадекватные хамы встречаются где угодно – Самые лучшие и интересные новости по теме: Приколы, животные, позор на развлекательном портале
Зоолог Брифер: ИИ помог им расшифровать хрюканье свиней с точностью 92%
| Голландские пищевики обратили внимание на аэродинамику | Fundamentals of Aerodynamics 5th edition by John D. Anderson. |
| Пассажиром «Москвича» в Рязанской области стала свинья | Бывший пилот «Макларена», «Рено» и «Хааса» Кевин Магнуссен высказался о борьбе в «Формуле-1» в последние годы и поделился планами: сезон-2021 он проводит в американской. |
Aerodynamics of perching birds could inform aircraft design
The lower the amount of air under the car, the faster it flows also thanks to the contribution of the flat under-car, which allows air to flow smoothly. Again, faster airflow means lower pressure under the car. The final consequence is that pressure difference versus the upper side of the car increases, leading to an increase in downforce generation. In conclusion, by setting the suspension travel we are also setting the amount of downforce the car is able to generate. The type of perturbations we may encounter are: E.
When the car accelerates, the nose of the car elevates, allowing a higher amount of air to enter under the car. The result is an increase in the pressure under the car, and less downforce is generated. This might increase downforce, but the braking effect reduces the airspeed, so the gain is minimal. The role of suspension in both cases is to mitigate this effect as soon as possible in order to recover the car stability and to generate sustained downforce again.
Marshal, Toyota Yaris WRC, Rally Catalunya 2019 pre-event test, October 2019 — image of a WRC car rolling — rolling, or when the weight of the vehicle shifts from its center of gravity to one side or another, allowing the entrance of air from both sides of the car due to loss of efficiency of side skirts , which also increases the pressure under the car as air flows slowly and, at the same time, by modifying the distribution of air under the car, generating preferential paths. The result is a loss of efficiency of the rear diffuser, as a heterogeneous distribution of air means different airspeeds across the diffuser, reducing its capacity of removing air under the car and, by extension, reducing the amount of downforce it can generate.
Ранее sfera. В Россельхознадзоре отмечают, что обстановка по АЧС в России остается умеренной, тогда как в ближайших странах ситуация по АЧС вызывает беспокойство экспертов sfera.
По результатам применения проект будет выпущен в тиражирование", - подчеркнул разработчик. Он отметил, что племенное хозяйство "Лазаревское" - крупнейшее в Тульской области, насчитывает более 60 тыс. Также в "Лазаревском" строится завод по производству семян, который должен быть введен в эксплуатацию в 2025 г. Директор по развитию технологий искусственного интеллекта ООО "Яндекс" Александр Крайнов назвал проект по неинвазивному взвешиванию свиней очень интересным использованием ИИ-решений в реальном мире. Я проникся прямо от первого слайда - первый раз видел, как данные меряют в тоннах. И главный вывод, который я для себя извлек, что не надо, видимо, рассказывать о результатах взвешивания, от этого нервничают и худеют, а зачем нам худые свиньи", - с юмором оценил доклад "Лазаревского" Александр Крайнов. Какие перспективы у ИИ в сельском хозяйстве Пресс-служба "Лазаревского" не смогла ответить на вопросы ComNews о перспективах коммерциализации программы по неинвазивному взвешиванию свиней, сообщив, что готовит релиз об этом на следующую неделю. В нескольких агрохолдингах также отказались обсуждать продукт "Лазаревского", сообщив, что разрабатывают аналогичные решения самостоятельно. Мы с уверенностью можем сказать, что отраслевое применение ИИ - это безусловный тренд, и ускорение темпов внедрения ИИ в отраслях - одна из задач, над которыми мы работаем", - отметили в пресс-службе Альянса в сфере ИИ.
В Австралии их около 24 миллионов. Участники исследования заявили, что ответственность за экологические последствия, конечно же, должны нести не кабаны. Контроль численности их должны вести люди. Проблему можно решить за счет отлова и охоты этих животных.
Свинья в скафандре стоит перед самолетом, генерирующим искусственный интеллект
Лорд Брабазон своим опытом опроверг теорию о том, что "свиньи не могут летать.". Experiments and simulations suggest that the airplane-like wing position adopted by some birds when they land helps to increase lift. Кроме Москвы, колонны автомобилей проехали по улицам Нижнего Новгорода и Севастополя.