The gauge pressure of water at A is 150.5 kPa. Water flows through the pipe at A with a velocity of 18 m/s, and out the pipe at B and C with the same velocity v. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mm at A, and at B and C the diameter is 25 mm. Pw = 1000 kg/m³. (Figure 1) Figure n 18 m/s 1 of 1 > Part A Determine the component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. F₁ = Submit Part B μA F₁ = Value Submit X Incorrect; Try Again; 5 attempts remaining Previous Answers Request Answer Determine the y component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. Express your answer to three significant figures and include the appropriate units. Units μÀ Value Request Answer ? Units ?

Elements Of Electromagnetics
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The gauge pressure of water at AA is 150.5 kPakPa. Water flows through the pipe at AA with a velocity of 18 m/sm/s, and out the pipe at BB and CC with the same velocity vv. Neglect the weight of water within the pipe and the weight of the pipe. The pipe has a diameter of 50 mmmm at AA, and at BB and CC the diameter is 25 mmmm . ρwρw = 1000 kg/m

Determine the xx component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium.
Express your answer to three significant figures and include the appropriate units.
 
Determine the yy component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium.
Express your answer to three significant figures and include the appropriate units.
### Educational Text on Fluid Mechanics

**Problem Description:**

The gauge pressure of water at point \( A \) is 150.5 kPa. Water flows through the pipe at \( A \) with a velocity of 18 m/s, and out of the pipe at points \( B \) and \( C \) with the same velocity \( v \). Neglect the weight of the water within the pipe and the weight of the pipe itself. The pipe has a diameter of 50 mm at \( A \), and at points \( B \) and \( C \), the diameter is 25 mm. The density of water \( \rho_w \) is 1000 kg/m\(^3\). [Figure 1]

**Figure Explanation:**

The figure illustrates a pipe system where water flows in and out through different sections. The flow enters from the right at point \( A \) with a velocity of 18 m/s and exits to the left at points \( B \) and \( C \) with velocity \( v \). The diagram shows directional arrows indicating the flow of water.

**Part A:**

Determine the \( x \)-component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium.

- Express your answer to three significant figures and include the appropriate units.

\[ F_x = \text{Value} \quad \text{Units} \]

- Submission options include previous answers and requesting answers. An incorrect submission will result in a prompt to try again with 5 attempts remaining.

**Part B:**

Determine the \( y \)-component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium.

- Express your answer to three significant figures and include the appropriate units.

\[ F_y = \text{Value} \quad \text{Units} \]

- Options to submit or request an answer are available.

This scenario involves applying principles of fluid dynamics and mechanics to solve for forces acting on the pipe due to the flow of water.
Transcribed Image Text:### Educational Text on Fluid Mechanics **Problem Description:** The gauge pressure of water at point \( A \) is 150.5 kPa. Water flows through the pipe at \( A \) with a velocity of 18 m/s, and out of the pipe at points \( B \) and \( C \) with the same velocity \( v \). Neglect the weight of the water within the pipe and the weight of the pipe itself. The pipe has a diameter of 50 mm at \( A \), and at points \( B \) and \( C \), the diameter is 25 mm. The density of water \( \rho_w \) is 1000 kg/m\(^3\). [Figure 1] **Figure Explanation:** The figure illustrates a pipe system where water flows in and out through different sections. The flow enters from the right at point \( A \) with a velocity of 18 m/s and exits to the left at points \( B \) and \( C \) with velocity \( v \). The diagram shows directional arrows indicating the flow of water. **Part A:** Determine the \( x \)-component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. - Express your answer to three significant figures and include the appropriate units. \[ F_x = \text{Value} \quad \text{Units} \] - Submission options include previous answers and requesting answers. An incorrect submission will result in a prompt to try again with 5 attempts remaining. **Part B:** Determine the \( y \)-component of force exerted on the elbow necessary to hold the pipe assembly in equilibrium. - Express your answer to three significant figures and include the appropriate units. \[ F_y = \text{Value} \quad \text{Units} \] - Options to submit or request an answer are available. This scenario involves applying principles of fluid dynamics and mechanics to solve for forces acting on the pipe due to the flow of water.
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