SNAS643C JULY 2014 – January 2016 HDC1000
PRODUCTION DATA.
NOTE
Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.
A HVAC or Thermostat are based on environmental sensors and a micro-controller which acquires data from humidity sensors and temperature sensors and controls the heating/cooling system. The collected data are then showed on a display that can be easily controlled by the micro controller. Based on data from the humidity and temperature sensor, the heating/cooling system then maintains the environment at customer-defined preferred conditions.
In a battery-powered HVAC or thermostat, one of the key parameters in the selection of components is the power consumption. The HDC1000, with its 1.2μA of current consumption (average consumption over 1s for RH and Temperature measurements) in conjunction with an MSP430 represents an excellent choice for the low power consumption, which extends the battery life. A system block diagram of a battery powered HVAC or Thermostat is shown in Figure 15.
In order to correctly sense the ambient temperature and humidity, the HDC1000 should be positioned away from heat sources on the PCB. Generally, it should not be close to the LCD and battery. Moreover, to minimize any self-heating of the HDC1000 it is recommended to acquire at a maximum sample rate of 1sps (RH + Temp). In home systems, humidity and the temperature monitoring rates of less than 1sps (even 0.5sps or 0.2sps) can be still effective.
When a circuit board layout is created from the schematic shown in Figure 15 a small circuit board is possible. The accuracy of a RH and temperature measurement depends on the sensor accuracy and the setup of the sensing system. The HDC1000 samples relative humidity and temperature in its immediate environment, it is therefore important that the local conditions at the sensor match the monitored environment. Use one or more openings in the physical cover of the HVAC to obtain a good airflow even in static conditions. Refer to the layout below ( Figure 19) for a PCB layout which minimizes the thermal mass of the PCB in the region of the HDC1000, which can improve measurement response time and accuracy.
The data showed below have been acquired with the HDC1000EVM. The environment conditions have been evaluated in a humidity chamber.
For soldering HDC1000, standard reflow soldering ovens may be used. The sensor is qualified to withstand soldering profile according to IPC/JEDEC J-STD-020 with peak temperatures at 260 °C. Refer to the document SNVA009 for more details on the DSBGA package. In the document refer to DSBGA package with bump size 0.5mm pitch and 0.32mm diameter.
When soldering the HDC1000 it is mandatory to use no-clean solder paste and no board wash shall be applied. The HDC1000 should be limited to a single IR reflow and no rework is recommended.
The HDC1000 may exhibit a negative RH offset due to either the thermal stress of soldering or settling of the humidity sensor. It will slowly settle when the humidity sensor is exposed to ambient conditions. If a faster settling is desired, the following hydration process can be used:
Store the PCB containing the HDC1000 at 85% RH, 85 degrees C, for 12 hours.
The humidity sensor is not a standard IC and therefore should not be exposed to volatile chemicals such as solvents or other organic compounds. If any type of protective coating must be applied to the circuit board, the sensor must be protected during the coating process.