Increased Human Comfort from Optimal Indoor Air Humidity

Increased Human Comfort from Optimal Indoor Air Humidity

Optimal humidity level in indoor air strongly contributes to human comfort. Key to successful humidification control starts with reliable humidity measurement.

Guidelines For Placing the Humidity Transmitters

• The sensor location should be carefully chosen to represent the conditions in the controlled space.
• Avoid locations close to the discharge of the supply air duct, near exterior doors and windows, and inside walls which are exposed to solar radiation.
• Locate sensors away from heat and moisture sources.
• Ensure that a gentle air flow is allowed around the humidity sensor. Avoid locations where air circulation is prevented e.g. by interior textiles or furniture.
• If humidity is centrally controlled at the air handler level, it is recommended to add additional space sensors to critical spots or problematic areas e.g. shower rooms.
• In duct installation, locate the sensor in a place where it can be easily maintained and calibrated. Make sure that the duct seams are tightly sealed to avoid air leakage.
• For supply air duct installations, select a robust humidity transmitter which withstands humidity fluctuations, condensation and outside air contaminants. Avoid locations near the cooling and heating coils.
• In outdoor installations, use a radiation shield to protect the sensor from precipitation and solar radiation.

 

Human comfort, productivity, and a sense of health and well-being are the positive outcome of a healthy indoor environment where the indoor air is fresh and free from odors, dust and other contaminants. Human comfort depends on a complex interaction of multiple variables with humidity being only one of them. However, optimizing both temperature and relative humidity satisfies the comfort requirements for a wider variety of occupants as opposed to regulating temperature only.

Low relative humidity in indoor air results in human discomfort. Headache, irritated eyes, sore throat, and dry skin are all symptoms of a dry indoor environment. Dry air lowers the natural defense against airborne infections and makes people vulnerable to the attack of viruses and other micro-organisms. In addition to the problems associated with low humidity, too high humidity can also cause problems. These problems are related to the growth and spread of unhealthy biological pollutants and to the damaging effect of moisture on the construction materials.

Typically humans are less sensitive to humidity than temperature. People generally fail to associate discomfort and potential health problems with variations in relative humidity. This is where a good technology can support the human senses. A reliable humidity measurement is the key to successful humidity control.

Recommendations for Indoor Air Humidity

The recommendations for indoor air relative humidity vary from country to country. The ASHRAE standard 55 specifies that to decrease the possibility of discomfort due to low humidity, the dew point temperature should not be less than 2.8°C (37°F). This equals to 30% relative humidity in 21°C. The upper dew point limit is specified to 16.7°C (47°F), which equals to 76% relative humidity in 21°C.

Health and Safety Executive in the United Kingdom recommends relative humidity in the range of 40 to 70% in the workplace environment. At higher temperatures, the relative humidity should be at the lower end of this range. Similarly OSHA, Occupational Safety & Health Administration in the United States, recommends controlling indoor air humidity in the range of 20-60%.

Humidity problems are often related to excess humidity, especially in colder climates. For example, The National Building Code of Finland states that humidity in indoor air shall not be high enough as to be damaging on a continual basis, nor shall condensation be allowed to concentrate on structures or their surfaces. The code further states that high levels of humidity shall not be allowed within ventilation systems in a way that will cause moisture damage, growth of microbes or microorganisms, or any other health hazards.

Capacitive Humidity Measurement — from Vaisala’s Innovation to an Industry Standard

Vaisala introduced the Vaisala HUMICAP® thin-film capacitive humidity sensor in 1973. Since then, Vaisala has become the market leader in relative humidity measurements and the thin-film capacitive humidity sensor has developed from one company’s innovation into a global industry standard.

Today, capacitive thin-film polymer humidity sensors are widely used in industrial and commercial applications. The sensor consists of a substrate on which a thin film of polymer is deposited between two conductive electrodes. The thin-film polymer absorbs and releases water vapor as the relative humidity of the surrounding air increases and decreases. The dielectric properties of the polymer film depend on the amount of absorbed water. A change in the relative humidity of the surrounding environment changes the capacitance of the sensor. The electronics of the instrument measure the capacitance and convert it into a humidity reading.

Vaisala HUMICAP® — Humidity Under Good Control

Relative Humidity Facts

• Relative humidity is the ratio of the partial pressure of water vapor in the air to the saturation vapor pressure of air at a defined temperature.
• The relative humidity in the indoor air is influenced by both air temperature and the water vapor content of the air. The warmer the air, the more water vapor it can contain and vice versa — the cooler the air, the lower capacity for water vapor content.
• Relative humidity is normally expressed as a percentage.
• The human comfort zone is around 30-60% relative humidity.

 

Vaisala HUMICAP® sensors are known for their accuracy, excellent long-term stability and negligible hysteresis. All instruments have been calibrated and adjusted by the manufacturer prior to shipping. Vaisala HUMICAP® contains a promise to the customers for quality and reliability. In typical HVAC applications this means measurement performance that lasts, offering convenience in maintaining the instruments in the field.

In humidity controlled applications, the humidity sensor is typically located in the supply air duct or even in an outdoor environment where condensation can occur. The unique capability of Vaisala HUMICAP® sensors to recover from condensation without changes in the measurement stability make them ideal for these applications.

The wide range of Vaisala HUMICAP® relative humidity and temperature instruments fits a large variety of applications, including the most demanding conditions. For calibration of fixed instruments and for spot-checking measurements, Vaisala offers a wide selection of portable and handheld meters.

Source: Vaisala