| SECTION
2 - DIFFUSERS - VARIABLE VOLUME |
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APPLICATIONS
- VAV
COOLING & HEATING
- VAV
COOLING & TERMINAL REHEAT
ADVANTAGES
-
Electric or pneumatic actuator
- TERMINAL
reheat
- Slaving
option
- Reversing
change-over
- Remote
setpoint option
- No
REGULAR maintenance
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1
INTRODUCTION
The
RICKARD VARIABLE GEOMETRY VARI-DISC CEILING DIFFUSER
The RICKARD VARIABLE GEOMETRY VARI-DISC CEILING DIFFUSER is designed for general building zones where uniform radial discharge is the most suitable and desirable supply air distribution pattern. The basic diffuser is available in a wide range of options to suit every individual requirement.
Optimum performance in terms of uniform air distribution and low noise levels has been combined with simple construction and aesthetically pleasing appearance to provide a unit which is both functional and reliable. All diffusers have a steel construction and are finished in a chip resistant baked epoxy powder coating which is available in a wide range of colours to suit architectural requirements.
2
OPERATION
GENERAL
DESCRIPTION
Room temperature is controlled by varying the supply air volume in accordance with demand. Volume control is achieved by moving a disc, known as the control disc, vertically up and down in the diffuser so as to vary the aperture through which air passes. This results in the “VARIABLE GEOMETRY” concept which effectively maintains constant air movement in the room throughout the range of control, from 100% down to approximately 30%.
The
position of the control disc is varied by means of a pneumatic
or electric actuator which drives the disc in response to
a signal received from the temperature controller. When used
with the RICKARD controller, the diffuser will control room
temperature on a proportional-integral basis. Air is discharged
in a 360 degree horizontal pattern. Maximum and minimum air
volumes may be adjusted to suit the particular design conditions.
For a detailed description of VAV systems refer to Section
1 of this catalogue.
MAINTENANCE
Although
the diffusers require no routine preventative maintenance,
all mechanical components as well as the actuator and controller
are accessible from below the ceiling. As a result of the
“modular” design of the diffusers, changing components
does not require highly skilled labour and can be carried
out with minimal disruption to room occupants.
3
DIFFUSER SELECTION
GENERAL
The first consideration when designing a system is to calculate the required air volume and temperature to satisfy room conditions at maximum heat loads. It is recommended that ducting is sized using the static-regain method. Velocities in branch ducts should be in the range (3.5-6m/s) 650 - 1200 ft/min. Thereafter the following should be considered:
THROW
This is the distance from the diffuser at which the air velocity has reduced to (0.25m/s) 50 ft/min when measured (25mm)1 in. below the ceiling (or from the wall) with the diffuser in the fully open position. Coning occurs when two airstreams travelling in opposite directions meet and result in a downward moving cone of air. Ideally diffusers should be spaced such that the distance between two diffusers is slightly less than the sum of their throws. Throw remains essentially constant throughout the range of air flow rates, a feature of the variable geometry diffuser.
NOISE
LEVEL REQUIREMENTS
This must be checked to ensure compliance with project specifications. The NC levels given in the tables on the next page are taken at a distance of (2m) 6 ft from the diffuser in a normal office environment. These represent only the noise regenerated by the diffuser and do not take into account any duct-borne noise. (To obtain approximate dBA readings, add 5 dB to the NC levels.)
DUCT
STATIC PRESSURE
Diffuser
performance has been established using diffuser neck TOTAL
pressure, although what is normally known and controlled is
duct STATIC pressure. What happens between the duct and the
diffuser depends on the length and type of flexible duct.
For simplicity, it can be assumed that duct STATIC pressure
approximates diffuser neck total pressure. This is a valid
assumption for systems where flexible duct lengths are not
excessive. The above can be explained briefly as follows:
The static pressure loss due to friction in the flexible duct
(±10Pa)(±0.05 in.w.g.) would normally be about
the same as the velocity pressure in the diffuser neck and
since total pressure is the sum of static and velocity pressures,
we can say that neck total pressure is approximately the same
as duct static pressure. Although the tables give diffuser
performance for neck total pressures ranging from (20-100Pa)
0.08 - 0.40 in.w.g., caution should be exercised when selecting
diffusers outside the range of (40-80Pa) 0.16 - 0.32 in.w.g.
At lower pressures air movement and induction may be insufficient
and at higher pressures draughts and excessive noise may result.
Best results are obtained when diffusers are selected at pressures
of (50-70Pa) 0.20 - 0.30 in.w.g. Bear in mind that all diffusers
on a particular branch will operate at the same static pressure,
as controlled by the pressure control damper. Diffusers which
are able to supply more air than required will be driven partially
closed by the temperature controller and the system becomes
self balancing.
NOTE:
Avoid placing restrictions (such as manually operated dampers or squashed flexible ducts) at any point in branch ducts. The reason for this being that at maximum flow these restrictions result in a significant static pressure loss (which for some cases may be desirable) but at minimum flow conditions offer virtually no resistance, which will result in the static pressure at the diffuser being too high.
4
CONTROLS
GENERAL
DESCRIPTION
The VARI-DISC diffuser can be supplied complete with electronic controls to give accurate and reliable proportional-integral cooling control to maintain a constant room temperature.
REVERSING
CHANGE-OVER
The REVERSING CHANGE-OVER module is a plug-in conversion. A change over sensor can be plugged into the Triac PCB, Interface PCB or Master control board. This changes the actuator from direct to reverse acting during winter when warm air is supplied. Normally, as the sensed temperature rises, the air volume from the terminal increases, while in the reverse mode, the air volume from the terminal will increase as the room temperature decreases. Practically, this means varying the volume of cold air to cool in summer and varying the volume of warm air to heat in winter. It is preferable to plug the change over sensor into the Triac PCB or Interface PCB so that you can easily mount the sensor in the supply air stream. Care must be taken to ensure that, if the diffuser has a heater fitted, this sensor is installed in such a way that it is not affected by radiant heat from the heater.
SLAVING
FACILITY
It is possible to control up to six diffusers from one controller i.e. one master diffuser and up to five slave diffusers.
POWER
SUPPLY
The controller requires a 24V AC power supply for operation. Diffusers may however have a 110 or 230/24V transformer which will be fitted to the master diffuser only.
Rickard
Air Diffusion Pty. Ltd. reserves the right to change specifications
and data without prior notice.
UNITED
STATES OFFICE
Rickard Air Diffusion, 1401 N. Plano Road, Richardson, TX. 75081
TEL: (972) 744 9090, FAX: (972) 238 0641
HEAD OFFICE RICKARD AIR DIFFUSION (PTY) LTD,
P.O. BOX 103 OTTERY 7808,
Tel : ++27 (021) 704 1533 Fax: ++27 (021) 704 1004
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