The present invention relates to refrigeration units for refrigerated vehicles, and more particularly relates to a refrigeration unit configured to drive a compressor directly by a refrigerating engine.
As described in Patent Document 1, refrigerated vehicles configured so that a trailer forming a refrigerator is towed by a tractor have conventionally been equipped with a refrigeration unit for cooling the interior of a refrigerator. A refrigerated vehicle of this type has been equipped with a sub-engine forming a refrigerating engine separate from a driving engine. For the refrigeration unit, a compressor is coupled to the sub-engine, and a refrigeration circuit is connected to the compressor. The compressor is driven by the sub-engine, and an evaporator of the refrigeration circuit evaporates refrigerant, resulting in cooling of the interior of the refrigerator.
For conventional refrigeration units for refrigerated vehicles, their refrigeration capacities are generally merely controlled in two stages. Hence, the conventional refrigeration units have not adapted to fluctuations in their refrigeration loads and thus have been inefficient.
More particularly, the operational capacity of the compressor has been only changed in two stages by controlling the rotational speed of the sub-engine in two stages. Consequently, even with a linear change in the refrigeration load, the refrigeration capacity has only changed in two stages. Therefore, the conventional refrigeration units have had a region providing an unnecessary capacity and thus have exhibited poor refrigeration efficiency.
The present invention has been made in view of the foregoing point and an object thereof is to improve the refrigeration efficiency of a refrigeration unit by efficiently providing the refrigeration capacity thereof.
A first aspect of the invention is directed to a refrigerated vehicle refrigeration unit configured to cool the interior of a refrigerator (13) of a refrigerated vehicle (10) and including: a refrigerating engine (30); a compressor (40) driven by the refrigerating engine (30); and a refrigeration circuit (70) connected to the compressor (40) and operable in a vapor compression refrigeration cycle. The refrigerated vehicle refrigeration unit includes a rotational speed controller (91) for linearly controlling fluctuations in a rotational speed of the refrigerating engine (30) such that a refrigeration capacity grows or declines in response to a refrigeration load.
A second aspect of the invention is directed to a refrigerated vehicle refrigeration unit configured to cool the interior of a refrigerator (13) of a refrigerated vehicle (10) and including: a refrigerating engine (30); a compressor (40) driven by the refrigerating engine (30); and a refrigeration circuit (70) connected to the compressor (40) and operable in a vapor compression refrigeration cycle. The refrigerated vehicle refrigeration unit includes a battery (51) for storing electric power; and an electric generator (50) for generating electric power by the rotational drive of the refrigerating engine (30) to store the generated electric power in the battery (51) and rotating by the electric power of the battery (51) to develop torque. Additionally, the refrigerating engine (30) is disconnectably connected to the compressor (40), and the electric generator (50) is connected to the compressor (40).
In a third aspect of the invention, the refrigerated vehicle refrigeration unit according to the first aspect of the invention may further include: a battery (51) for storing electric power; and an electric generator (50) for generating electric power by the rotational drive of the refrigerating engine (30) and allowing the battery (51) to store the generated electric power. A fan motor (7a) for the refrigeration circuit (70) may be selectively connectable to the electric generator (50) and the battery (51) such that power is fed from at least one of the electric generator (50) and the battery (51) to the fan motor (7a).
In a fourth aspect of the invention, the refrigerated vehicle refrigeration unit according to the first aspect of the invention may further include: a battery (51) for storing electric power; and an electric generator (50) for generating electric power by the rotational drive of the refrigerating engine (30) to store the generated electric power in the battery (51) and rotating by the electric power of the battery (51) to develop torque. The refrigerating engine (30) may be disconnectably connected to the compressor (40), and the electric generator (50) may be disconnectably connected to the compressor (40).
In a fifth aspect of the invention, in the refrigeration unit according to any one of the first through fourth aspects of the invention, the compressor (40) may include a plurality of compressors (40), and the plurality of compressors (40) may be connected in parallel and connected to the refrigeration circuit (70).
In a sixth aspect of the invention, the refrigeration unit according to any one of the first through fourth aspects of the invention may further include an auxiliary motor (60) disconnectably connected to the compressor (40) and driven by electric power of an external power source.
In a seventh aspect of the invention, in the refrigeration unit according to the second or third aspect of the invention, the electric generator (50) may be selectively connectable to an external power source and the battery (51).
<Operation>
According to the first aspect of the invention, the compressor (40) is driven by the torque of the refrigerating engine (30), and the refrigeration circuit (70) performs a cooling operation, thereby cooling the interior of the refrigerator (13). When the refrigeration load of the refrigerator (13) fluctuates, the rotational speed controller (91) linearly controls the rotational speed of the refrigerating engine (30) in response to the fluctuations in the load, resulting in improved efficiency.
According to the second aspect of the invention, the compressor (40) is driven by the torque of the refrigerating engine (30), and the refrigeration circuit (70) performs a cooling operation, thereby cooling the interior of the refrigerator (13). Meanwhile, for example, if the refrigeration load is small, the refrigerating engine (30) is stopped while the electric power of the battery (51) allows the electric generator (50) to rotate. This rotation drives the compressor (40). In this way, the cooling operation of the refrigeration circuit (70) is achieved.
In the third aspect of the invention, the fan motor (7a) for the refrigeration circuit (70) rotates by the electric power of the electric generator (50) or the battery (51). In particular, the compressor (40) is stopped, and the cooling of the interior of the refrigerator (13) is continued only by the fan motor (7a).
In the fourth aspect of the invention, the compressor (40) is driven in a low rotational speed range of the refrigerating engine (30) or any other range by the electric power of the battery (51).
In the fifth aspect of the invention, the number of the plurality of compressors (40) is controlled, thereby controlling the refrigeration capacity.
In the sixth aspect of the invention, if the refrigerating engine (30) cannot be driven, the compressor (40) is driven by the auxiliary motor (60). In this way, the cooling operation of the refrigeration circuit (70) is achieved.
In the seventh aspect of the invention, if the refrigerating engine (30) cannot be driven, the electric generator (50) drives the compressor (40). In this way, the cooling operation of the refrigeration circuit (70) is achieved.
According to the above-described present invention, fluctuations in the rotational speed of the refrigerating engine (30) are linearly controlled so that the refrigeration capacity grows or declines in response to the refrigeration load. Therefore, an unnecessary refrigeration capacity is not provided, for example, as compared with the conventional case in which the rotational speed of a refrigerating engine is controlled in two stages. This improves cooling efficiency, resulting in energy savings.
Furthermore, as compared with a unit that is volume-controlled by driving an electric generator using a refrigerating engine (30) and driving a motor of a compressor (40) using the power of this electric generator as in the past, losses arising from motor efficiency, power losses from the electric generator to the motor, or other losses are not caused. This improves the efficiency of the refrigeration unit.
According to the second aspect of the invention, since the electric generator (50) and the battery (51) are provided, the refrigerating engine (30) is driven at a constant rotational speed. Meanwhile, if the refrigeration load is reduced, the refrigerating engine (30) is stopped, the electric power stored in the battery (51) allows the electric generator (50) to develop torque, and the rotation of the electric generator (50) drives the compressor (40). Consequently, the power of the refrigerating engine (30) and the electric power of the battery (51) can be selectively used. This can provide the refrigeration capacity matched with the refrigeration load while permitting energy savings, resulting in improved efficiency.
According to the third aspect of the invention, the electric power generated by the electric generator (50) drives the fan motor (7a). Therefore, the fan motor (7a) can form an alternating motor, resulting in improved efficiency.
Moreover, if the refrigeration load is small, the rotation of the refrigerating engine (30) is stopped, and only the fan motor (7a) is driven by the electric power stored in the battery (51), thereby maintaining the indoor temperature only by an air blowing operation. As a result, the operating time of the refrigerating engine (30) can be reduced.
According to the fourth aspect of the invention, in a low rotational speed range of the refrigerating engine (30), the refrigerating engine (30) is stopped, the electric power stored in the battery (51) allows the electric generator (50) to develop torque, and the rotation of the electric generator (50) can drive the compressor (40). In other words, the electric generator (50) can double as a motor to drive the compressor (40). Consequently, the refrigerating engine (30) can be used in its high-efficiency range, resulting in further energy savings.
According to the fifth aspect of the invention, since the refrigeration unit is equipped with the plurality of compressors (40), the number of operating one or ones of the compressors (40) is controlled, thereby extensively adjusting the refrigeration capacity in response to the rotational speed range of the refrigerating engine (30). This adjustment allows the refrigeration capacity to adapt to extensive refrigeration loads.
According to the sixth aspect of the invention, since the auxiliary motor (60) is provided, an operation of the refrigeration circuit (70) can be continued, for example, also during the stop period of the sub-engine (30). This can increase the range of use for the refrigeration unit.
According to the seventh aspect of the invention, the electric generator (50) is selectively connectable to an external power source and the battery (51). Therefore, the electric generator (50) can double as a motor. As a result, the number of components can be reduced.
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
As shown in
The trailer (11) includes a trailer body (13), i.e., a refrigerator, and a refrigeration unit (20) for a trailer, i.e., a refrigeration unit for a refrigerated vehicle. The refrigeration unit (20) is placed on the front end surface of the trailer body (13), i.e., the surface thereof near the tractor (12).
As shown in
The sub-engine (30) is provided separately from a driving engine and configured as an exclusive engine for driving the refrigeration unit (20) so that a belt (21) is wound around a pulley (31) fitted onto a drive shaft of the sub-engine (30).
The compressors (40) are scroll compressors and configured as so-called open compressors so that pulleys (41) fitted onto respective drive shafts of the compressors (40) are coupled through the belt (21) to the pulley (31) of the sub-engine (30). In other words, the compressors (40) are mechanically coupled to the sub-engine (30) and driven by the torque of the sub-engine (30). Although not shown, the pulleys (41) or other components for the compressors (40) are provided with disconnecting mechanisms, such as clutches. Thus, the compressors (40) are disconnectably coupled to the sub-engine (30).
A refrigerant pipe (71) for the refrigeration circuit (70) operable in a vapor compression refrigeration cycle is coupled to the compressors (40). The two compressors (40) are connected in parallel to the refrigeration circuit (70).
Although not shown, the refrigeration circuit (70) includes a condenser, an expansion mechanism, and an evaporator. Refrigerant circulates in the following manner: Refrigerant discharged from the compressors (40) is condensed by the condenser, decompressed by the expansion mechanism, then evaporated by the evaporator, and returned to the compressors (40). The indoor air of the trailer body (13) is cooled by the evaporator, thereby cooling the interior of the trailer body (13).
Furthermore, the refrigeration circuit (70) includes fans (72) for the condenser and evaporator. Fan motors (7a) are coupled to the fans (72).
For the electric generator (50), a pulley (52) fitted onto a drive shaft of the electric generator (50) is coupled through another belt (21) to the pulley (31) of the sub-engine (30). The electric generator (50) generates electric power by the torque of the sub-engine (30). Although not shown, the pulley (52) or any other component for the electric generator (50) is provided with a disconnecting mechanism, such as a clutch. Thus, the electric generator (50) is disconnectably coupled to the sub-engine (30).
The battery (51) is connected to the electric generator (50) to store the power generated by the electric generator (50).
The electric generator (50) is electrically wired to the fan motors (7a) so that the fan motors (7a) are driven by the electric power generated by the electric generator (50). Furthermore, the fan motors (7a) are electrically wired also to the battery (51) and selectively connected to the electric generator (50) and the battery (51) so as to be driven by at least one of the electric power from the electric generator (50) and the electric power from the battery (51).
The fan motors (7a) are formed of alternating motors. The direct-current power supplied from the electric generator (50) and the battery (51) is converted into alternating-current power, and then the resultant alternating-current power is supplied to the fan motors (7a).
Furthermore, the electric generator (50) and the battery (51) feed power also to control devices.
The standby motor (60) is connectable to an external power source and permits a freezing operation of the refrigeration circuit (70) also during the period during which the refrigerated vehicle (10) is parked in a garage or the like. For the standby motor (60), a pulley (61) fitted onto a drive shaft of the standby motor (60) is coupled through the associated belt (21) to the pulley (31) of the sub-engine (30) so as to be coupled to the compressors (40). The pulley (61) or any other component for the standby motor (60) is provided with a disconnecting mechanism, such as a clutch. Thus, the standby motor (60) is disconnectably coupled to the compressors (40). In other words, the standby motor (60) drives the compressors (40) during the stop period of the sub-engine (30) and is formed of a compact motor capable of rotating at high speed.
A controller (90) is connected to the sub-engine (30) and provided with a rotational speed control unit (91) forming a rotational speed controller for the sub-engine (30). The rotational speed control unit (91) controls the rotational speed of the sub-engine (30). In other words, the rotational speed controller is configured, for example, to control a throttle motor for driving a throttle valve of the sub-engine (30).
Furthermore, the rotational speed control unit (91) linearly controls fluctuations in the rotational speed of the sub-engine (30) such that the refrigeration capacity of the refrigeration unit grows or declines in response to the refrigeration load. More particularly, the rotational speed control unit (91) linearly increases the rotational speed of the sub-engine (30) on the basis of, for example, the temperature differential between an indoor temperature and a desired temperature in the following manner: With an increase in the temperature differential and an associated increase in the refrigeration load, the refrigeration capacity grows. Conversely, the rotational speed control unit (91) linearly decreases the rotational speed of the sub-engine (30), for example, in the following manner: With a decrease in the temperature differential between the indoor temperature and the desired temperature and an associated decrease in the refrigeration load, the refrigeration capacity declines.
-Operational Behavior—
Next, a description will be given of the behavior of the above-described refrigeration unit (20) for the refrigerated vehicle (10) during a cooling operation thereof.
First, when the sub-engine (30) is driven separately from the driving engine, the torque of the sub-engine (30) is transmitted through the associated belt (21) to the compressors (40). Thus, the rotation of the sub-engine (30) permits the rotational drive of the two compressors (40). The rotational drive of the compressors (40) allows the compressors (40) to compress refrigerant in the refrigeration circuit (70). The refrigerant circulates in the following manner: The refrigerant discharged from the compressors (40) is condensed by the condenser, decompressed by the expansion mechanism, then evaporated by the evaporator, and returned to the compressors (40). The indoor air of the trailer body (13) is cooled by the evaporator, thereby cooling the interior of the trailer body (13).
Meanwhile, although not shown, the temperature of the indoor air of the trailer body (13) is sensed, thereby detecting the refrigeration load on the basis of the temperature differential between the indoor temperature and the desired temperature. When the temperature differential between the indoor temperature and the desired temperature becomes greater and the refrigeration load accordingly increases, the rotational speed control unit (91) linearly increases the rotational speed of the sub-engine (30) so that, with the increase in the temperature differential, the refrigeration capacity grows. On the other hand, when the temperature differential between the indoor temperature and the desired temperature becomes smaller and the refrigeration load accordingly decreases, the rotational speed control unit (91) linearly decreases the rotational speed of the sub-engine (30) so that, with the decrease in the temperature differential, the refrigeration capacity declines.
Consequently, the cooling capacity grows in response to the increase in the refrigeration load, resulting in reliable cooling of the interior of the trailer body (13).
Furthermore, the refrigeration capacity is controlled in the following manner: If the refrigeration load is small, only one of the two compressors (40) is driven, and if the refrigeration load is large, both of the two compressors (40) are driven.
Meanwhile, the rotation of the sub-engine (30) allows the electric generator (50) to generate electric power. The electric power of the electric generator (50) is supplied to the fan motors (7a), thereby driving the fans (72). The generated electric power of the electric generator (50) is fed also to control devices, such as the controller (90), and fed also to the battery (51) so as to be stored therein.
On condition that a freezing operation of the refrigeration circuit (70) is performed also during the period during which the refrigerated vehicle (10) is parked in a garage or the like, the standby motor (60) is connected to an external power source. The drive of the standby motor (60) allows the torque of the standby motor (60) to drive the compressors (40). As a result, the refrigeration circuit (70) continues its cooling operation. In this case, while the coupling between the compressors (40) and the sub-engine (30) is interrupted, the standby motor (60) is coupled to the compressors (40).
-Advantages of Embodiment—
As described above, according to this embodiment, fluctuations in the rotational speed of the sub-engine (30) are linearly controlled so that the refrigeration capacity grows or declines in response to the refrigeration load. Therefore, an unnecessary refrigeration capacity is not provided, for example, as compared with the conventional case in which the rotational speed of a sub-engine is controlled in two stages. This improves cooling efficiency, resulting in energy savings.
Furthermore, as compared with a unit that is volume-controlled by driving an electric generator using a sub-engine (30) and driving a motor of a compressor (40) using the power of this electric generator as in the past, losses arising from motor efficiency, power losses from the electric generator to the motor, or other losses are not caused. This improves the efficiency of the refrigeration unit.
Moreover, since the refrigeration unit is equipped with the two compressors (40), the number of operating one or ones of the compressors (40) is controlled, thereby extensively adjusting the refrigeration capacity in response to the rotational speed range of the sub-engine (30). This adjustment allows the refrigeration capacity to adapt to extensive refrigeration loads.
In addition, the electric power generated by the electric generator (50) drives the fan motors (7a). Therefore, the fan motors (7a) can form alternating motors, resulting in improved efficiency.
Furthermore, since the standby motor (60) is provided, an operation of the refrigeration circuit (70) can be continued, for example, also during the stop period of the sub-engine (30). This can increase the range of use for the refrigeration unit.
<Other Embodiments>
The above embodiment of the present invention may be configured as follows.
In the above embodiment, the compressors (40) are always driven during the cooling operation. However, if the refrigeration load is small, the rotation of the sub-engine (30) may be stopped, and only the fan motors (7a) may be driven by the electric power stored in the battery (51), thereby maintaining the indoor temperature only by an air blowing operation. As a result, the operating time of the sub-engine (30) can be reduced.
In a low rotational speed range of the sub-engine (30), the sub-engine (30) may be stopped, the electric power stored in the battery (51) may allow the electric generator (50) to develop torque, and the rotation of the electric generator (50) may drive the compressors (40). In other words, the electric generator (50) may double as a motor to drive the compressors (40). In this case, coupling between the compressors (40) and the sub-engine (30) is interrupted. Consequently, the sub-engine (30) can be used in its high-efficiency range, resulting in further energy savings.
Although in the above embodiment the rotational speed control unit (91) is provided, the rotational speed control unit (91) may be omitted. More particularly, the sub-engine (30) may be driven at a constant rotational speed. Meanwhile, if the refrigeration load is reduced, the sub-engine (30) may be stopped, the electric power stored in the battery (51) may allow the electric generator (50) to develop torque, and the rotation of the electric generator (50) may drive the compressors (40). In this case, the power of the sub-engine (30) and the electric power of the battery (51) can be selectively used. This provides the refrigeration capacity matched with the refrigeration load while permitting energy savings, resulting in improved efficiency.
Although in the above embodiment the electric generator (50) and the standby motor (60) are both provided, the electric generator (50) may double as the standby motor (60). In other words, the electric generator (50) may be selectively connectable to an external power source and the battery (51). As a result, the number of components can be reduced.
Although in the above embodiment the two compressors (40) are provided, a single compressor (40) may be provided in the present invention. Alternatively, three or more compressors (40) may be provided.
Although in the above embodiment the standby motor (60) is provided, it does not always need to be provided in the first, second and other aspects of the invention. In other words, the standby motor (60) may be provided as an optional item.
Although in the above embodiment the refrigerated vehicle (10) having a trailer was described, the refrigerated vehicle (10) may be a refrigerated truck or any other refrigerated vehicle.
The above embodiments are mere essentially preferable examples, and are not intended to limit any scopes of the present invention, applicable subjects, and usage.
As described above, the present invention is useful for refrigeration units for refrigerated vehicles for cooling, for example, the indoor air in the interior of a trailer body.
Number | Date | Country | Kind |
---|---|---|---|
2007-016342 | Jan 2007 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2008/050975 | 1/24/2008 | WO | 00 | 7/24/2009 |