Moist Chlorine & Hydrogen Psychrometric or Mollier Chart

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In summary, the conversation discusses the production of Cl2 and H2 as gaseous products in the electrolysis of brine, along with aqueous NaOH. The speaker is seeking information on the maximum moisture that Cl2 and H2 can hold at a specific temperature and pressure, as well as potential solutions for dehumidifying the gases using coolers. The speaker has been unable to find this information or estimate preliminary values without proper psychrometric data and is requesting a link to the data or other alternatives.
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In our electrolysis of brine, Cl2 & H2 are produced as gaseous products along with aqueous NaOH. In this scenario I require what amount of maximum moisture can Cl2 or H2 hold up at specific temperature & pressure (precisely 85celsius & 1.2bar absolute). Two coolers (shell/tube exchanger with chilled water on shell side) are planned to dehumidify these two gases.

I have searched hard but without proper psychrometric data am unable to even estimate preliminary values. Link to data or other alternatives are highly welcome.

regards,
 
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I'm sorry you are not finding help at the moment. Is there any additional information you can share with us?
 
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Sir, what further information should I share. I think am pretty much clear
 

1. What is a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart?

A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart is a graphical representation of the thermodynamic properties of moist air. It shows the relationship between temperature, humidity, and other important properties such as enthalpy, specific volume, and dew point temperature. It is used to analyze and solve problems related to air conditioning, ventilation, and other processes involving moist air.

2. How is a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart used?

A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart is used to determine the condition of moist air at a specific temperature and humidity. It can also be used to find the amount of moisture in the air, the amount of water vapor that needs to be added or removed to achieve a desired condition, and to calculate the energy required for heating or cooling processes involving moist air.

3. What are the advantages of using a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart?

A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart is a convenient and accurate tool for analyzing and solving problems related to moist air. It allows for quick and easy visualization of the relationships between different properties of air, making it useful for design and troubleshooting in various industries such as HVAC, refrigeration, and meteorology. It also eliminates the need for complex calculations, saving time and effort.

4. What are the limitations of a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart?

A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart is based on a set of assumptions and may not accurately represent real-world conditions. It assumes that air behaves like an ideal gas and that there is no heat transfer between the air and its surroundings. Additionally, the chart is limited to a specific range of temperature and humidity values, and may not be applicable for extreme conditions.

5. How is a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart different from a Psychrometric Chart?

A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart and a Psychrometric Chart are both used to analyze moist air, but they differ in the properties they represent. A Moist Chlorine & Hydrogen Psychrometric or Mollier Chart includes properties such as enthalpy and specific volume, while a Psychrometric Chart includes properties such as wet bulb temperature and relative humidity. Additionally, a Moist Chlorine & Hydrogen Psychrometric or Mollier Chart is based on the use of chlorine and hydrogen as reference gases, while a Psychrometric Chart uses air as a reference gas.

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