Tindak Tutur Ilokusi dalam Interaksi antara Pedagang dengan Pembeli di Pasar Panam Kecamatan Tampan Kota Pekanbaru

This research entitled The Illocutionary Speech Act in Interaction Between Traders to Buyers in the Market Panam Kecamatan Tampan Pekanbaru City. A problem that investigated in this research is kind of a speech act ilokusi contained in the interaction between traders to buyers in the market panam. This research aims to understand the type of a speech act ilokusi contained in the interaction between traders with buyers market panam d sub-district handsome pekanbaru. The research is qualitative research methods descriptive. The object of this research in the form of tuturan uttered by traders to buyers in the market panam handsome sub-district pekanbaru. Data collection techniques in this research using simak, technique record, technique and techniques logged. The result of this research shows that kind of a speech act ilokusi found was a speech act ilokusi assertive, directive, komisif, expressive, and declarative. Ilokusi assertive that found is assertive said , made known , and complain. Ilokusi directive is directive order, pleading, suggesting, asked, urge and entreat, give you, challenge, sent, invite, and ordered. Ilokusi komisif found was komisif offer, promising, ability and said. Ilokusi expressive found was expressive of saying thank you and blame. Ilokusi declarative found was declarative pointed. Research is expected can be beneficial for for an audience to deepen the science of pragmatik particularly on ilokusi a speech act

Crosswise Stream of Cu-H₂O Nanofluid with Micro Rotation Effects: Heat Transfer Analysis

The present study focuses on a crosswise stream of liquid-holding nano-sized particles over an elongating (stretching) surface. Tiny particles of copper are added into base liquid (water). The influence of the micro rotation phenomenon is also considered. By means of appropriate transformations non-linear coupled ordinary differential equations are attained that govern the flow problem. The Runge–Kutta–Fehlberg scheme, together with the shooting method, is engaged to acquire results numerically. Micropolar coupling parameter, microelements concentration and nanoparticles volume fraction effects are examined over the profiles of velocity, temperature and micro-rotation. Moreover, heat flux and shear stress are computed against pertinent parameters and presented through bar graphs. Outcomes revealed that material constant has increasing effects on normal components of flow velocity; however, it decreasingly influences the tangential velocity, micro-rotation components and temperature profile. Temperature profile appeared to be higher for weak concentration of microelements. It is further noticed that normal velocity profile is higher in magnitude for the case of strong concentration (n = 0) of microelements, whereas tangential velocity profile is higher near the surface for the case of weak concentration (n = 0.5) of microelements. An increase of 3.74% in heat flux is observed when the volume fraction of nanoparticles is increased from 1 to 5%

Crosswise Stream of Cu-H2O Nanofluid with Micro Rotation Effects: Heat Transfer Analysis

The present study focuses on a crosswise stream of liquid-holding nano-sized particles over an elongating (stretching) surface. Tiny particles of copper are added into base liquid (water). The influence of the micro rotation phenomenon is also considered. By means of appropriate transformations non-linear coupled ordinary differential equations are attained that govern the flow problem. The Runge–Kutta–Fehlberg scheme, together with the shooting method, is engaged to acquire results numerically. Micropolar coupling parameter, microelements concentration and nanoparticles volume fraction effects are examined over the profiles of velocity, temperature and micro-rotation. Moreover, heat flux and shear stress are computed against pertinent parameters and presented through bar graphs. Outcomes revealed that material constant has increasing effects on normal components of flow velocity; however, it decreasingly influences the tangential velocity, micro-rotation components and temperature profile. Temperature profile appeared to be higher for weak concentration of microelements. It is further noticed that normal velocity profile is higher in magnitude for the case of strong concentration (n = 0) of microelements, whereas tangential velocity profile is higher near the surface for the case of weak concentration (n = 0.5) of microelements. An increase of 3.74% in heat flux is observed when the volume fraction of nanoparticles is increased from 1 to 5%

Humanism, Civic

status: Published onlin