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Smart Buildings for Indoor Smart Air Quality Monitoring

2022-09-20
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Illustration: © IoT For All

Digital transformation by itself is not that exciting, nor does it motivate people unless it is connected to a bigger purpose. Post COVID-19, when employees are still wondering whether to return to their workplaces, send their children to school, or travel to their favorite destinations, the office buildings, educational institutions, and airports are under heavy scrutiny for the highest performance standards. The health of these spaces and the indoor air quality of these buildings are under a tight spotlight. Smart air quality monitoring is a helpful solution. With climate change and greenhouse gas emissions, new and fresh thinking is needed from every global citizen who can play a role towards sustainability that reduces the impact on the environment and climate change.

'Indoor air quality plays an important role in the overall health and well-being of building occupants as well as the environment.' -WaylayClick To Tweet

Hyperaware smart buildings: healthy green buildings and indoor air quality

Challenges to the Office Space

As office space workers and tenants are coming back to the buildings with great expectations, the building owners, landlords, and employee health and safety officials have to provide adequate measures and transparency toward clean, healthy buildings and are required to promptly respond to occupants’ requests. The US Green Building Council, EPA, and LEEDS have converged to create a common set of indoor air quality standards that are governed by a key set of parameters such as:

  • CO2: A natural compound in the air with an average outdoor concentration of 300-400ppm. The indoor levels are higher. Anything beyond 900ppm can be considered not healthy. Future smart buildings should keep the CO2 level close to 600ppm.
  • CO: It is an odorless and colorless lethal gas and is one of the most dangerous compounds in the indoor environment. The National Institute for Occupational Safety and Health (NIOSH) has recommended an exposure limit of 35ppm for an eight-hour workday.
  • VOC: Volatile organic compounds are chemicals found in many products we use in our daily lives. They can irritate the eyes, nose, and throat, and cause difficulty breathing. They are emitted by many common building materials, including carpeting, hardwood flooring, upholstery and even marble surfaces.
  • PM2.5: Particulate matter is a dangerous form of pollution as the size of the particle is so small (2.5 micrometers or less in diameter) that it can get into the lungs causing many adverse effects. Their threshold limit value is 25 μg / 3.
  • Radon: It is a radioactive gas formed by the decay of natural Uranium in the soil. It is carcinogenic and EPA recommends a level limit of 4 pCi/L. 

Solution Guidelines

LEED provides a framework for healthy, efficient, carbon, and cost-saving green buildings. They are a critical part of addressing the healthy buildings, climate crisis, and meeting ESG goals. The ASHRAE (American Society for Heating, Refrigerating, and Air-conditioning Engineers) advances the heating, cooling, and ventilation design of buildings. Both of these frameworks play a role in how we design, operate, and service future smart buildings and today’s buildings that can be retrofitted with IoT sensors for smart air quality monitoring.

Let’s take a look at an example of how spaces in a building can be automated for LEED-certified indoor air quality based on how the building is occupied.

Air Quality Monitoring Example

We will build a building occupancy and floor area-based automation control function to regulate indoor air quality based on ANSI/ASHRAE 62.1 – 2019 standards. The purpose of the ASHRAE standard is to specify minimum ventilation rates and other measures intended to provide indoor air quality (IAQ) that is acceptable to human occupants and that minimizes adverse health effects.

The occupancy density and floor area of a space drive the outdoor airflow intake that is required in the breathing zone (Vbz) of the occupiable space. The amount of fresh outdoor air required for the ventilation zone should not be less than the value determined in the following equation:

Vbz = Rp * Pz + Ra *  Az

  • Az = zone floor area, the net occupiable floor area of the ventilation zone, ft2 (m2)
  • Pz = zone population, the number of people in the ventilation zone during use
  • Rp = outdoor airflow rate required per person
  • Ra = outdoor airflow required per unit area

Let’s assume there is an office building of Waylay in Austin, Texas with the following floors/occupiable spaces.

  1. Floor 1: Main entry lobby (2,000 sq. ft.), Breakroom (1,000 sq. ft.), Office Space (3,000 sq. ft.)
  2. Floor 2: Breakroom (1,000 sq. ft.), Office Space (3,000 sq. ft.

Office Building Example

Anomaly Condition: Assume the breakroom occupancy count reached 70 during a company event when employees from different organizations gathered to meet and eat lunch together. This event triggers an exceed in the occupancy threshold of 50 per 1000 sq. ft. The condition persisted for 1 hour (12 pm – 2pm CST) and then occupancy fell below the threshold (50) by 3pm CST. Then the occupant density finally reached zero by 6:00 pm CST. The ventilation rate needs to be adjusted at every threshold crossing and then set to a minimum threshold for zero occupancy. Additionally, for energy conservation, the lights will need to be turned off in the breakroom when there is no occupancy.

Ventilation Rate Example

Low-Code Implementation

  1. Model a resource, Waylay Austin. Create resources floor 1 and floor 2 as children of resource ‘Waylay Austin’ building.
  2. Model a resource breakroom 1 as a child resource of floor 1 and another breakroom 2 as a child resource for floor 2.
  3. Create metadata attributes (area_sqft) with value = 1000 for resources breakroom 1 and breakroom.
  4. Create meta data attribute (area_sqft) with value = 2000 for resources lobby 1 for floor 1.
  5. Write a rule to run against the breakroom 1 of floor 1 where the occupancy sensor of breakroom 1 sends the data shown on the above table.

Start with occupancy density (medium = 40) where no thresholds are exceeded, and set the HVAC control system ventilation_rate to 320 cfm. Then, after some time at 12pm CST, occupancy increases to 70 and exceeds the threshold (50). At this time, we increase the ventilation_rate to 470 cfm. Send a command to the VAV controller to supply extra air to the space by 470 cfm – 320 cfm = 150 cfm or +46 percent extra air supply. Also, raise a WARNING alarm (occupancy in the breakroom of building A / floor 1 has exceeded the capacity threshold) for the facility manager.

Then, when the occupancy goes down to 50, reduce the ventilation_rate (air supply) to 370 cfm. When the occupancy goes down to zero, then reduce the ventilation_rate to 120 cfm or a difference of 370 cfm – 120 cfm / 370 cfm = -67.5% percent.

Smart Air Quality Monitoring Importance

Indoor air quality plays an important role in the overall health and well-being of building occupants as well as the environment. Poor air quality in the buildings can lead to numerous adverse health problems, such as nausea, headaches, breathing problems such as asthma, skin irritations, and even cancer. In fact, since people spend almost 90 percent of their time indoors, indoor air quality has a significant impact on people’s health and productivity. 

On the other hand, data from the U.S. Department of Energy shows buildings account for 40 percent of all U.S. energy use and waste 30 percent of the energy they consume. Therefore, the balancing act of energy consumption and wastage against indoor air quality can be maintained by strictly following the ANSI/ASHRAE and LEED guidelines. This is achievable through hyperautomation systems which can sense the real-time occupant capacity, indoor air parameters, and air flows in various building zones, and converge them with contextual data from IT systems, outdoor air quality, and occupant feedback in real-time.

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  • Automation
  • Building Automation
  • Digital Transformation
  • Health and Wellness
  • Sensors

  • Automation
  • Building Automation
  • Digital Transformation
  • Health and Wellness
  • Sensors

参考译文
用于室内智能空气质量监测的智能建筑
数字转型本身并不那么令人兴奋,也不会激励人们,除非它与一个更大的目标相联系。新冠肺炎疫情后,当员工们还在考虑是否返回工作岗位、送孩子上学或前往他们喜欢的目的地时,办公楼、教育机构和机场正在接受严格审查,要求达到最高的绩效标准。这些空间的健康状况和这些建筑的室内空气质量受到密切关注。智能空气质量监测是一个有用的解决方案。随着气候变化和温室气体排放,每一个全球公民都需要新的和新鲜的思维,以便在减少对环境和气候变化的影响的可持续发展方面发挥作用。由于办公空间的工作人员和租户带着极大的期望回到大楼,大楼所有者、房东和雇员健康和安全官员必须为清洁、健康的大楼提供充分的措施和透明度,并被要求迅速回应居住者的要求。美国绿色建筑委员会、环境保护署和利兹联合制定了一套通用的室内空气质量标准,该标准由一系列关键参数控制,例如:LEED为健康、高效、碳排放和节约成本的绿色建筑提供了一个框架。它们是解决健康建筑、气候危机和实现ESG目标的关键部分。ASHRAE(美国采暖、制冷和空调工程师协会)促进了建筑的采暖、制冷和通风设计。这两个框架都对我们如何设计、操作和服务未来的智能建筑和今天的建筑起着重要作用,这些建筑可以用物联网传感器进行智能空气质量监测。让我们来看看一个例子,如何根据建筑物的占用情况,自动化建筑空间以达到leed认证的室内空气质量。我们将根据ANSI/ASHRAE 62.1 - 2019标准建立一个基于建筑物占用率和楼层面积的自动化控制功能,以调节室内空气质量。ASHRAE标准的目的是规定最低换气率和其他措施,旨在提供人类居住者可接受的室内空气质量(IAQ),并尽量减少对健康的不利影响。空间的居住密度和建筑面积驱动可居住空间的呼吸区(Vbz)所需的室外气流进气口。通风区所需的室外新鲜空气量不应小于以下等式中确定的值:Vbz = Rp * Pz + Ra * az让我们假设在德克萨斯州奥斯汀有一座Waylay的办公楼,其楼层/可占用空间如下:异常情况:假设在一次公司活动中,当来自不同组织的员工聚集在一起开会并一起吃午餐时,休息室占用数达到70。该事件触发了超过每1000平方英尺50人的入住率阈值。这种情况持续了1小时(12点-下午2点),然后入住率在下午3点低于阈值(50)。然后居住者密度最终在CST下午6点达到零。通风率需要在每个阈值交叉处进行调整,然后设置为零占用的最小阈值。此外,为了节约能源,当没有人入住时,休息室的灯需要关掉。 从没有超过阈值的居住密度(中= 40)开始,将HVAC控制系统的通风率设置为320立方厘米。然后,在CST中午12点一段时间后,入住率增加到70人,并超过阈值(50人)。这时,我们将通风量增加到470立方英尺。向VAV控制器发送一个命令,向空间提供额外的空气470 cfm - 320 cfm = 150 cfm或+ 46%额外空气供应。此外,向设施经理发出WARNING警报(a / 1层休息室的占用率已超过容量阈值)。然后,当入住率下降到50时,将通风量(送风量)降低到370立方英尺。当入住率降至零时,将通风率降至120立方厘米或370立方厘米- 120立方厘米/ 370立方厘米= -67.5%的差额。室内空气质量对建筑物居住者以及环境的整体健康和福祉起着重要作用。建筑物中糟糕的空气质量会导致许多不利的健康问题,如恶心、头痛、哮喘等呼吸问题、皮肤刺激,甚至癌症。事实上,由于人们几乎90%的时间都呆在室内,室内空气质量对人们的健康和生产力有重大影响。另一方面,美国能源部(U.S. Department of Energy)的数据显示,建筑占美国能源使用总量的40%,浪费了30%的能源消耗。因此,通过严格遵循ANSI/ASHRAE和LEED准则,可以保持能源消耗和浪费与室内空气质量的平衡。这可以通过超自动化系统实现,该系统可以实时感知居住者容量、室内空气参数和不同建筑区域的空气流量,并将它们与IT系统的相关数据、室外空气质量和居住者反馈实时融合。
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