[0001] The present invention relates to refrigerant cycle apparatus comprising: a compressor,
a condenser, an expansion means and an evaporator connected in series with each other;
means for repeatedly starting and stopping said compressor; and means for isolating
refrigerant on a high pressure side of said compressor from said refrigerant on a
low pressure side of said compressor when said compressor is stopped
[0002] Such apparatus is known from US-A-3093976.
[0003] One conventional refrigeration cycle apparatus includes a compressor, a condenser,
an expansion device such as a capillary tube or an expansion valve, and an evaporator
with these components sequentially coupled in series with each other. When the compressor
is stopped, the pressure of the refrigerant on a high pressure side is balanced with
the pressure of the refrigerant on the low pressure side. As the compressor is started,
the difference between the pressures of the high pressure side and the low pressure
side is gradually increased until the apparatus is brought to an ordinary operating
state. When the compressor is accordingly repeatedly started and stopped, the high
pressure side refrigerant is balanced with the low pressure side refrigerant each
time the apparatus is stopped. During these times, the refrigerant liquid stored on
the low pressure side in an evaporator is drawn into the compressor. The presence
of the liquid refrigerant in the condenser increases the load on the compressor at
the time of restarting the compressor. This lowers the coefficient of performance
(hereinafter abbreviated as "COP") of the apparatus as compared with that during continuous
operation.
[0004] This problem is mitigated by the apparatus described in US-A-3093976, but when the
refrigeration cycle apparatus is used in an air temperature conditioning system capable
of operating in both cooling and heating modes the refrigerant flow must be reversible.
Conventional apparatus of this type is relatively expensive to manufacture and is
relatively large.
[0005] An object of the invention is to simplify the construction of such apparatus thus
enabling less expensive manufacture and reduction in size.
[0006] Another object of the invention is to enable the expansion coefficient of the apparatus
to be varied between the heating and cooling modes in a simple manner.
[0007] According to the invention, the apparatus defined in the first paragraph of this
specification is characterised in that said expansion means comprises at least two
capillary tube portions and in that valve means is connected across one portion whereby
the effective length of said expansion means may be changed.
[0008] The foregoing objects and other objects as well as the characteristic features of
the invention will become more apparent and more readily understandable by the following
description and the appended claims when read in conjunction with the accompanying
drawings, the sole Figure of which is a schematic structural view showing a preferred
embodiment of refrigeration cycle apparatus of the invention.
[0009] Reference is now made to the drawing showing a preferred embodiment of the refrigeration
cycle apparatus, constructed according to the invention. Reference numeral l designates
generally a compressor. A refrigerant gas compressed at high temperature and high
pressure by the compressor l is fed through a check valve 2 and a four-way valve 3
into a condenser 4. The refrigerant dissipates heat in the condenser 4 and is condensed
to a high temperature and high pressure liquid. The refrigerant liquid, increased
in temperature and pressure by the condenser 4, is passed through a capillary tube
l2 where the refrigerant becomes a low temperature, low pressure liquid and a switching
element l4 which acts as a valve and from there is introduced into an evaporator 7.
The low temperatur e and low pressure refrigerant liquid in the evaporator
7 absorbs heat and thus evaporates to a gas. This refrigerant gas is again fed through
the four-way valve 3 into an accumulator 8 which isolates the refrigerant liquid which
cannot be evaporated in the evaporator 7 and is retained in the liquid state and which
returns only the refrigerant gas again to the compressor l. While the compressor l
is operating, the apparatus repeats the refrigeration cycle.
[0010] Reference numeral 9 illustrates a fan for the condenser 4 and l0 a fan for the evaporator
7. The four-way valve 3 is a change-over or switching valve which operates so that
the condenser 4 can be used as an evaporator and the evaporator 7 used as a condenser.
[0011] When this refrigeration cycle apparatus is used in a room air temperature conditioning
system, the evaporator 7 is used as an indoor side heat exchanger, and the condenser
4 is used as an outdoor side heat exchanger. In the illustrated cooling mode, the
apparatus is operated in a refrigeration cycle which in the heating mode is switched
by the four-way valve 3 so that the indoor side heat exchanger 7 is used as a condenser
and the outdoor side heat exchanger 4 is used as an evaporator.
[0012] The air temperature conditioning system operates to detect the temperature in the
room by a temperature detector or thermostat (not shown) and to start or stop the
compressor l so as to maintain the room temperature at a set temperature by operating
or stopping the refrigeration cycle apparatus.
[0013] The switching element l4, which isolates the compressor l, is constructed so as to
open when the compressor l is started and to close when the compressor l is stopped.
The element l4 and the check valve 2 function to isolate high pressure side refrigerant
and low pressure side refrigerant when the compressor l is stopped.
[0014] In this refrigeration cycle apparatus used in an air temperature conditioning system
as described above, when the compressor l is repeatedly started and stopped to maintain
the room temperature at a set value, the element l4 is simultaneously opened and closed.
Since the element l4 is closed when the compressor l is stopped, the high temperature
and high pressure refrigerant liquid in the condenser 4 does not flow into the capillary
tubes l2, l3 and accordingly does not flow into the evaporator 7. On the other hand,
since the check valve 2 is provided at the exhaust side of the compressor l, the refrigerant
gas in the condenser 4 and the condensed refrigerant liquid cannot return to the compressor
l.
[0015] When the compressor l is restarted, the high pressure side refrigerant in the refrigeration
cycle is isolated from the low pressure side refrigerant. Since the element l4 is
then opened, a desired pressure difference between the high and low pressure side
refrigerant can be attained in short time and the apparatus can reach ordinary operating
state in short time.
[0016] The conventional refrigerant cycle not incorporating such an isolating device requires
about five minutes to reach the ordinary operation state after restarting. On the
other hand, the refrigeration cycle apparatus of the invention requires only about
one minute and twenty seconds to make the transition.
[0017] It is noted that the aforesaid switching element l4 may be a solenoid valve 5 or
another type of switching valve and may be any type which closes when the compressor
l is stopped and opens when the compressor l is started.
[0018] There is also provided a further capillary tube l3 in parallel with a check valve
l5 which is constructed to pass the refrigerant in the illustrated cooling mode and
to block the refrigerant in the non-illustrated heating mode with the valve 3 switched
to its other position. The check valve l5 is provided to effectively alter the length
of the total capillary tube l2, l3 since the apparatus will operate more efficiently
if the expansion coefficient of the refrigerant is varied between the cooling mode
and the heating mode in such a manner that the capillary tube is effectively increased
in length in the heating mode.
[0019] With two capillary tubes l2 and l3 used instead of an expansion valve, the apparatus
can be inexpensively constructed, even if the check valve l5 is added.
[0020] The switching element l4 is constructed to compare the pressure P₂, determined by
the output side refrigerant gas temperature of the evaporator 7 as detected by a heat
sensitive tube provided between the outlet of the evaporator 7 and the inlet of the
compressor l, with the pressure P₁ of the refrigerant exhausted from the capillary
tube l2, and to open when P₂ > P₁ and to close when P₂ < P₁, in the same manner as
described above.
1. Refrigeration cycle apparatus comprising: a compressor (l), an condenser (4), an
expansion means (l2,l3) and an evaporator (7) connected in series with each other;
means for repeatedly starting and stopping said compressor (l); and means (2,l4) for
isolating refrigerant on a high pressure side of said compressor (l) from said refrigerant
on a low pressure side of said compressor (l) when said compressor (l) is stopped,
characterised in that said expansion means comprises at least two capillary tube portions
(l2,l3) and in that valve means (l5) is connected across one portion (l3) whereby
the effective length of said expansion means may be changed.
2. Apparatus according to claim l wherein said valve means comprises a check valve
(l5).
3. Apparatus according to claim l or 2 wherein said effective length is increased
in a heating mode.
4. Apparatus according to any one of the preceding claims wherein said isolating means
comprises a switching element (l4) provided between said capillary tube portions (l2,l3)
and arranged to close fully when said compressor (l) is stopped and to open fully
when said compressor (l) is started.