For this diagram of an industrial pressure washer system, x = 2 ft, y = 5 ft, z = 9 ft, Q = 3.4 ft3/s, and the hose diameter is 3 in. Assuming a head loss of 4 ft is derived over the distance from point the jet, what is the pressure at point 2 if the jet from the nozzle is 1 in. in diameter? Assume a = 1.0 throughout. x↓↓ O 535164 psi O 372383 psi O 2586 psil O 4996 psi 2 Z Nozzle

Structural Analysis
6th Edition
ISBN:9781337630931
Author:KASSIMALI, Aslam.
Publisher:KASSIMALI, Aslam.
Chapter2: Loads On Structures
Section: Chapter Questions
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### Industrial Pressure Washer System Analysis

#### Diagram Description
The diagram illustrates an industrial pressure washer system with various dimensions and parameters labeled:

- **Dimensions**:
  - \( x = 2 \, \text{ft} \)
  - \( y = 5 \, \text{ft} \)
  - \( z = 9 \, \text{ft} \)

- **Flow Characteristics**:
  - Flow rate (\( Q \)) = \( 3.4 \, \text{ft}^3/\text{s} \)
  - Hose diameter = \( 3 \, \text{in} \)

- **Assumptions**:
  - Head loss from point 2 to the jet = \( 4 \, \text{ft} \)
  - Jet nozzle diameter = \( 1 \, \text{in} \)
  - \(\alpha = 1.0\) throughout the system

#### Objective
Calculate the pressure at point 2 given the parameters and conditions stated.

#### Diagram Features
- The system includes a hose connected to a nozzle, with the positions and height differences clearly marked.
- The nozzle design ensures specific fluid dynamics that contribute to the system’s pressure and flow characteristics.

#### Question
What is the pressure at point 2 if the jet from the nozzle is \( 1 \, \text{in} \) in diameter?

#### Answer Choices
- \( 535164 \, \text{psi} \)
- \( 372383 \, \text{psi} \)
- \( 2586 \, \text{psi} \)
- \( 4996 \, \text{psi} \)
Transcribed Image Text:### Industrial Pressure Washer System Analysis #### Diagram Description The diagram illustrates an industrial pressure washer system with various dimensions and parameters labeled: - **Dimensions**: - \( x = 2 \, \text{ft} \) - \( y = 5 \, \text{ft} \) - \( z = 9 \, \text{ft} \) - **Flow Characteristics**: - Flow rate (\( Q \)) = \( 3.4 \, \text{ft}^3/\text{s} \) - Hose diameter = \( 3 \, \text{in} \) - **Assumptions**: - Head loss from point 2 to the jet = \( 4 \, \text{ft} \) - Jet nozzle diameter = \( 1 \, \text{in} \) - \(\alpha = 1.0\) throughout the system #### Objective Calculate the pressure at point 2 given the parameters and conditions stated. #### Diagram Features - The system includes a hose connected to a nozzle, with the positions and height differences clearly marked. - The nozzle design ensures specific fluid dynamics that contribute to the system’s pressure and flow characteristics. #### Question What is the pressure at point 2 if the jet from the nozzle is \( 1 \, \text{in} \) in diameter? #### Answer Choices - \( 535164 \, \text{psi} \) - \( 372383 \, \text{psi} \) - \( 2586 \, \text{psi} \) - \( 4996 \, \text{psi} \)
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