11t,4 | Carrier 48TJ016-028 instruction

LED ON

18
17
16- -- - LED OFF	_ED ON
16- -- - LED OFF

E14

LED O;

_<	LED ON-- --

11"t,4

lO
				I					LED OFF
9									{
40	45	50	55	65	70	75	80	85	90	95	100
				DEGREES	FAHRENHEIT

Fig. 38 --Outside Air Temperature

Changeover Set Points

Outdoor Enthalpy Changeover -- For enthalpy control, tic-

cessoq enthalpy sensor (part number HH57AC078) is required. Replace the stan&ud outdoor dry bulb temperature sensor with the accessory enthalpy sensor in the same mount- ing location. See Fig. 32. When the outdoor tfir enthalpy rises above the outdoor enth_@y changeover set point, the outdoor- air damper moves to its minimum position. The outdoor enthalpy changeover set point is set with the outdoor enthalpy

set point potentiometer on the EconoMiSerIV controllel: The set points are A, B, C, and D. See Fig. 40. The factory-installed 620-ohm jumper must be in place across terminals SR and SR+ on the EconoMiSerIV controllel: See Fig. 32 and 41.

Differential Enthalpy Control -- For differential enthalpy

control, the EconoMiSerIV controller uses two enthalpy sen-

sors (HH57AC078 and CRENTDIF004A00), one in the out- side air and one in the return airstream or the EconoMiSerIV

frmne. The EconoMiSerIV controller compares the outdoor tfir enthalpy to the return tfir enthalpy to determine EconoMiSerIV use. The controller selects the lower enthalpy air (return or out- door) for cooling. For example, when the outdoor air has a low-

er enthalpy than the return air and is below the set point, the EconoMiSerIV opens to bring in outdoor air for free cooling.

Replace the standard outside air ch_ bulb temperature sen- sor with the accessory enth_dpy sensor in the same mounting location. See Fig. 32. Mount the return air enthalpy sensor in

the return airstream. See Fig. 39. The outdoor enthalpy changeover set point is set with the outdoor enth_flpy set point

potentiometer on the EconoMiSerIV controllel: When using this mode of changeover control, turn the enth_flpy set point potentiometer fiJlly clockwise to the O setting.

NOTE: Remove 620-ohm resistor if differential enthalpy sen- sor is installed.

Indoor Air Quality (IAQ) Sensor [nput -- The IAQ input can be used for demand control ventilation control based on the

level of CO2 measured in the space or return air duct.

Mount the accessory IAQ sensor according to manufacturer specifications. The IAQ sensor should be wired to the AQ and AQI terminals of the controllel: Adjust the DCV potentiome- ters to correspond to the DCV voltage output of the indoor tfir

quality sensor at the user-determined set point. See Fig. 42.

If a sepmate field-supplied transformer is used to power the

IAQ sensor, the sensor must not be grounded or the EconoMiSerlV control bomd will be damaged.

Exhaust Set Point Adjustment -- The exhaust set point will determine when the exhaust fan runs based on dmnper position (if accessory power exhaust is installed). The set point is modi- fied with the Exhaust Fan Set Point (EXH SET) potentiometel:

See Fig. 37. The set point represents the cktmper position above which the exhaust fan will be turned on. When there is a

c_dl for exhaust, the EconoMiSerIV controller provides a

	RETURN AIR
IAQ	TEMPERATURE
SENSOR	OR ENTHALPY
	SENSOR

Fig. 39 --Return Air Temperature or

Enthalpy Sensor Mounting Location

45 _+15 second delay before exhaust fan actiw_tion to allow the

dampers to open. This delay _fllows the damper to reach the appropriate position to avoid unnecessary fan overload.

Minimum Position Control -- There is a minimum damper

position potentiometer on the EconoMi$erIV controllel: See Fig. 37. The minimum dmnper position mainttfins the mini- mum airflow into the building during the occupied period.

When using demand ventilation, the minimum &tmper po- sition represents the minimum ventilation position for VOC

(volatile organic compound) ventilation requirements. The maximum demand ventilation position is used for fully occu- pied ventilation.

When demand ventilation control is not being used, the minimum position potentiometer should be used to set the oc- cupied ventilation position. The maximum demand ventilation position should be turned fully clockwise.

Adjust the minimum position potentiometer to _fllow the minimum amount of outdoor air. as required by local codes, to enter the building. Make minimum position adjustments with at least 10° F temperature difference between the outdoor and return-air temperatures.

To determine the minimum position setting, perform the following procedure:

1.Calculate the appropriate mixed-air temperature using the following formula:

OA	+ (TR	RA	) = TM
(To x l-T-if(]-)		x _	) = TM

To = Outdoor-Air Temperature

OA = Percent of Outdoor Air

TR = Return-Air Temperature

RA = Percent of Return Air

TM = Mixed-Air Temperature

As an example, if local codes require 10% outdoor air

during occupied conditions, outdoor-_fir temperature is 60 IF.and return-air temperature is 75 IF.

(60 x. 10) + (75 x .90) = 73.5 F

48TJ016-028 specifications

The Carrier 48TJ016-028 is a notable model in the range of packaged rooftop units designed by Carrier, a leader in heating, ventilation, and air conditioning (HVAC) solutions. Tailored specifically for commercial applications, these units provide a blend of efficiency, durability, and reliability, making them suitable for a variety of settings, including offices, retail spaces, and industrial environments.

One of the standout features of the 48TJ series is its energy-efficient performance. Equipped with high-efficiency scroll compressors, these units offer superior cooling capacity while minimizing energy consumption. This aligns with modern sustainability goals, helping businesses reduce their carbon footprint and operational costs. Additionally, the 48TJ units comply with stringent industry standards, such as the ASHRAE 90.1 energy efficiency guidelines, ensuring that users receive a product that meets modern energy performance benchmarks.

The 48TJ016-028 units also include advanced technologies that enhance performance and user comfort. The inclusion of a sophisticated microprocessor control system facilitates precise temperature regulation, allowing for an optimal balance of cooling and heating based on real-time conditions. Moreover, the user-friendly controls make it easy for facility managers to monitor system performance and make adjustments as necessary.

Another notable characteristic of the 48TJ series is its flexible installation options. These rooftop units are designed for easy integration into existing building structures and can be installed on flat or pitched roofs. Their compact design and lightweight construction simplify the installation process while minimizing structural impacts on buildings.

Durability is paramount in the design of the 48TJ units as well. The cabinets are constructed from high-quality materials with corrosion-resistant coatings, ensuring a long lifespan even in harsh environmental conditions. The systems are also equipped with robust insulation to reduce sound levels and improve overall operating efficiency.

Furthermore, the Carrier 48TJ016-028 units offer various options for customization. Users can choose from different airflow configurations, heating options, and accessories, allowing for tailored solutions that meet specific requirements. Whether you are looking for a unit with enhanced filtration, economizer capabilities, or advanced humidity control, the 48TJ series provides the flexibility needed for diverse applications.

In summary, the Carrier 48TJ016-028 units deliver a compelling combination of energy efficiency, advanced technology, and robust construction, making them an ideal choice for commercial HVAC needs. With their versatile features and customizable options, they stand out as reliable solutions for maintaining comfortable indoor environments.