 |
Description  |
|
|
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates in general to transport refrigeration, and more
specifically to air delivery systems for transport refrigeration units.
2. Description of the Prior Art
It is common in the transport refrigeration industry to have a dual speed
prime mover, such as a Diesel engine, connected to drive a refrigerant
compressor at a selected one of high and low speeds, such as 2200 RPM and
1400 RPM. The speed setting is responsive to the cooling or heating
capacity demanded by a thermostat which compares the temperature of a
served space with a temperature set point. If the condenser and evaporator
blowers are directly driven by the engine, the air flow drops when the
engine speed drops. This is desirable for the condenser blower, as the
requirements on the condenser blower are reduced at the lower
refrigeration capacity. This may or may not be desirable for the
evaporator blower, depending upon the temperature set point. If the set
point is set for unfrozen loads, such as produce, it is desirable to
maintain a high air circulation rate in the served space at all times,
regardless of compressor speed, in order to maintain a uniform temperature
in the cargo and prevent "top freezing". If the set point is set for
frozen loads, the temperature variation of the served space is not as
critical, as long as all points of the cargo are well below the freezing
point. Thus, reducing the air flow in the served space at the lower speed
is beneficial, as the reduced power draw by the blower and the reduction
of "fan heat" due to reduced compression and agitation of the air,
translate into increased cooling capacity, adding as much as 10 to 15%
capacity, and reduced fuel consumption as well.
Thus, while some systems include means for automatically maintaining the
evaporator air flow constant regardless of compressor speed, this is not
always advantageous, and can be a disadvantage.
It would be desirable, and it is the object of the present invention, to
provide an air delivery arrangement for a transport refrigeration system
in which the speed of the condenser blower is directly proportional to the
speed of the prime mover, while the speed of the evaporator blower is
independently variable, adjustable up and down with respect to the speed
of the prime mover.
SUMMARY OF THE INVENTION
Briefly, the present invention is an air delivery system for a transport
refrigeration unit which includes a prime mover having at least two
operational speeds, such as a Diesel engine, a compressor, a condenser, an
evaporator, a blower for the condenser, a blower for the evaporator, and
an adjustable speed arrangement for the evaporator blower. As used herein,
the term "blower" means any suitable air delivery unit, including
centrifugal blowers and axial flow fans.
The adjustable speed arrangement includes a jack shaft driven by the prime
mover having a fixed pulley which drives the condenser blower at a speed
directly proportional to the speed of the prime mover, and a variable
pulley. The variable pulley is linked by a belt which also links a pulley
which drives the evaporator blower, and an idler pulley. The position of
the idler pulley is controlled by a linear actuator to tension the belt
and select the pitch diameter of the variable pulley which will provide
the desired evaporator air flow for the temperature set point, at the
current prime mover speed. If the prime mover speed changes, the linear
actuator will select a new pitch diameter if the cargo requires a
substantially constant volume of air. If the temperature set point is
changed from a point above freezing, to one below freezing, or vice versa,
the affect of a speed change may be varied to select different pitch
diameters, or to maintain pitch diameters, as desired.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention may be better understood and further advantages and uses
thereof more readily apparent when considered in view of the following
detailed description of exemplary embodiments, taken with the accompanying
drawings, in which:
FIG. 1 is a perspective view of a transport refrigeration system having an
air delivery arrangement constructed according to the teachings of the
invention;
FIG. 2 is an elevational view of the variable speed portion of the air
delivery arrangement shown in FIG. 1 illustrating the movement of an idler
pulley by a linear actuator to select a desired pitch diameter of a
variable pulley;
FIG. 3 is a graph which plots RPM versus pitch diameter, illustrating
exemplary evaporator blower speeds available at high and low prime mover
speeds; and
FIG. 4 is a flow diagram of an exemplary control algorithm which may be
used to select the position of the linear actuator which in turn selects
the pitch diameter of the variable pulley shown in FIGS. 1 and 2.
DESCRIPTION OF PREFERRED EMBODIMENTS
U.S. Pat. No. 4,551,986, which is assigned to the same assignee as the
present application, discloses a transport refrigeration unit of the type
which may be modified to utilize the teachings of the invention, and this
patent is hereby incorporated into the specification of the present
application by reference.
Referring now to the drawings, and to FIG. 1 in particular, there is shown
a diagrammatic perspective view of a transport refrigeration system 10
constructed according to the teachings of the invention. Transport
refrigeration system 10 includes a prime mover 12, which is preferably a
Diesel engine having at least two solenoid selectable operational speeds,
such as 2200 RPM and 1400 RPM, commonly called "high speed" (HS) and "low
speed" (LS), respectively. Prime mover 12 includes a crankshaft 13 which
drives a refrigerant compressor 14, either directly or via a pulley
arrangement, and compressor 14 circulates refrigerant in a closed path
which includes a condenser 16 and an evaporator 18. U.S. Pat. No.
4,735,055, which is assigned to the same assignee as the present
application, may be referred to for a typical refrigerant circuit for
transport refrigeration systems, and this patent is hereby incorporated
into the specification by reference.
Transport refrigeration system 10 includes an air delivery arrangement 20
for the condenser 16 and evaporator 18 which includes a jack shaft 22
journaled for rotation and driven by the prime mover 12 by a drive
arrangement 23, an output shaft 24 journaled for rotation, a condenser
blower 26, a fixed speed drive arrangement 28 for driving the condenser
blower 26 at a speed directly proportional to the speed of the prime mover
12, an evaporator blower 30, and an adjustable speed drive arrangement 32
for driving the evaporator blower at selectable speeds. Longitudinal axes
34, 36 and 38 of crankshaft 13, jack shaft 22 and output shaft 24,
respectively, are all disposed in a predetermined spaced, parallel
relation.
Drive arrangement 23 for driving jack shaft 22 includes a crankshaft pulley
40, a driven pulley 42 fixed to jack shaft 22, and a V-belt 44 which links
or couples pulleys 40 and 42.
Drive arrangement 28 for driving condenser blower 26 at a speed directly
proportional to the speed of prime mover 12 includes a driving pulley 46
fixed to rotate with jack shaft 22, a pulley 48 journaled for rotation
about output shaft 24 via bearings 50, and a V-belt 52 which links pulleys
46 and 48.
Drive arrangement 32 for driving evaporator blower 30 at selectable speeds
includes an adjustable or variable pulley 54 having a first pulley face 56
which is fixed to jack shaft 22, and a second pulley face 58 which is
axially slidable upon jack shaft 22. A spring seat 60 is fixed to jack
shaft 22, in spaced relation from pulley 54, and a spring 62 is disposed
between seat 60 and the slidable face 58 of pulley 54, to bias pulley 54
towards the maximum pitch diameter. Drive arrangement 32 further includes
a driven pulley 64 which is fixed to output shaft 24, and an idler pulley
66. Idler pulley 66 is driven in a guided path by a linear actuator 68,
which may be electrical, as shown, or hydraulic. Control 70 provides
signals for actuator 68, which control the position of an actuating rod 72
to which idler pulley 66 is mounted. As shown more clearly in FIG. 2,
which is an enlarged elevational view of adjustable speed drive
arrangement 32, the actuator rod 72 of actuator 68 may be connected to a
link 74 via a pivot pin 76, and link 74 may be connected to the shaft 78
of pulley 66. A V-belt 80 links variable pulley 54, driven pulley 64 and
idler pulley 66.
Linear actuator 68 is controllable over a predetermined stroke to control
the position of idler pulley 66, the tension in V-belt 80, and the
effective pitch diameter of variable pulley 54. As shown in FIG. 2, when
the linear actuator 68 is at one end of its stroke in which actuator rod
72 has the shortest extension, the tension in V-belt 80 is the greatest,
causing V-belt 80 to move pulley face 58 outward against the bias of
spring 62 to the minimum pitch diameter, which in turn provides the lowest
speed for output shaft 24 which drives evaporator blower 30. The solid
line positions of the movable elements of drive arrangement 32 in FIG. 2
illustrate the minimum pitch diameter condition just described.
When linear actuator 68 extends rod 72 to the maximum, the tension in
V-belt 80 is reduced, spring 62 forces pulley face 58 towards face 56, the
maximum pitch diameter of pulley 54 is achieved, and output shaft 24 is
driven at the maximum speed for the currently used prime mover speed. This
condition is shown in broken outline in FIG. 2.
FIG. 3 is a graph which plots RPM versus pitch diameter of pulley 54 at
prime mover speeds of 2200 RPM and 1400 RPM, for an exemplary embodiment
of the invention in which the pitch diameters of pulleys 40, 42, 46, 48
and 64 are 5.75 inches, 4.65 inches, 5.15 inches, 7.95 inches, and 6.0
inches, respectively. Solid curves 82 and 84 indicate practical speed
ranges for evaporator blower 30 when prime mover 12 is operating at 2200
RPM and 1400 RPM, respectively. Broken line curves 86 and 88 indicate
suitable constant condenser blower speeds at prime mover speeds of 2200
RPM and 1400 RPM, respectively.
IT will be noted that at the higher prime mover speed of 2200 RPM, the
condenser blower 26 has a speed of 1770 RPM, and the speed of the
evaporator blower 30 may be varied above and below 1770 RPM, as well as
above and below the prime mover speed. At high speed the maximum pitch
diameter, e.g., 6 inches, of pulley 54 is not used, with the pitch
diameter being varied from 2.75 inches to 5.25 inches, providing an RPM
that varies from 1250 RPM to 2380 RPM. A pitch diameter of 3.9 inches will
provide an RPM for output shaft 24 substantially the same as the RPM of
the condenser blower 26. Linear actuator 68 may be controlled using a
small number of steps to provide the points indicated in the graph, or it
may be controlled using many steps to provide many more operational pitch
diameters, as desired.
At the lower prime mover speed of 1400 RPM, the condenser blower 26 has a
speed of 1125 RPM, and the speed of the evaporator blower 30 may be
controlled above and below the prime mover speed of 1400 RPM, i.e., from
1125 RPM, the same as the condenser blower speed, using the 3.9 inch pitch
diameter, to a speed of 1730 RPM using the maximum 6 inch pitch diameter.
The smallest pitch diameter 2.75 inches is not used during the low prime
mover speed. Thus, for example, if it is desired to provide a large volume
of air flow for a cargo of fresh produce, a pitch diameter of 5.25 or 3.9
inches may be selected when prime mover 12 is operating at high speed,
changing to a pitch diameter of 6 inches when the prime mover speed is
changed to low speed. The choice between 5.25 and 3.9 inch pitch diameters
at high speed may be made dependent upon the set point selected. For set
points above but relatively close to freezing, the 5.25 inch pitch
diameter may be selected, while set points above about 50.degree. F., for
example, may be used to select the 3.9 inch pitch diameter, to limit the
load on prime mover 12.
FIG. 4 is an exemplary control algorithm or program 90 which may be used by
control 70 to control the position of linear actuator 68, which in turn
selects a pitch diameter of pulley 54 and the speed of evaporator blower
30. Program 90 is entered at 92 and step 94 checks to see if refrigeration
system 10 is in a defrost mode. If system 10 is in defrost, a small pitch
diameter is required and step 96 outputs a signal to linear actuator 68
which selects the 3.9 inch pitch diameter, for example. The program then
exits at 98 until it is called again, which may be several times a second.
If refrigeration system 10 is not in defrost, step 100 determines if the
temperature set point has been set above freezing, i.e., above 32.degree.
F. If it is set above freezing, the program advances to step 102 which
determines if the prime mover 12 is operating at high speed. If it is,
step 104 if engine load limiting is required by checking to see if the
selected temperature set point is equal to above some predetermined
relatively high value T, such as 50.degree. F. If the set point is
relatively high, compressor 14 is required to pump more pounds of
refrigerant per minute, increasing the load on prime mover 12. Thus, to
limit engine loading, the fan load is reduced by proceeding to step 96
which selects the 3.9 inch pitch diameter. If the set point is below T, a
higher fan load is acceptable and step 104 advances to step 106 which
outputs a signal to linear actuator 68 which selects a pitch diameter of
5.25 inches. The program then exits at 98.
If step 102 finds that the prime mover 12 is operating at low speed, step
108 selects the 6.0 inch pitch diameter.
When step 100 finds that the set point has been selected to control a
frozen load, step 100 proceeds to step 110 which checks the prime mover
speed. If prime mover 12 is operating at low speed, step 96 selects the
3.9 inch pitch diameter. If step 110 finds the prime mover operating at
high speed, step 110 proceeds to step 112 to determined how close the
actual load temperature is to set point. If the actual temperature exceeds
set point by a predetermined value N, step 96 selects the 3.9 inch pitch
diameter, and if the actual temperature of the served space is closer to
set point than N, step 114 selects the 2.75 inch pitch diameter.
In summary, there has been disclosed a new air delivery system for a
transport refrigeration unit which provides a wide latitude of control
over the evaporator blower speed, enabling the proper or optimum speed to
be selected for both fresh and frozen loads, at different prime mover
speeds.
* * * * *
|
|
 |
|
 |
Description |
|
