JP3006005B2 - Operation control device for refrigeration equipment - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operation control device for a refrigerating apparatus that performs a defrost operation for melting frost on an evaporator. In particular, the present invention
It relates to measures to reduce the defrost operation time to a necessary minimum.

(Prior Art) Conventionally, as disclosed in Japanese Patent Application Laid-Open No. 59-199774, for example, a refrigerating apparatus including an external unit having a compressor and a condenser and an internal unit having an evaporator has been known. Have been. This type of refrigeration apparatus performs a defrost operation using hot gas from the compressor when the continuous operation time in the refrigeration mode in-range elapses a predetermined time until the intake gas temperature of the compressor reaches a predetermined set temperature. By this operation, frost formation on the evaporator in the refrigerator can be removed, and a decrease in refrigeration capacity can be prevented.

(Problems to be Solved by the Invention) By the way, the above-mentioned conventional refrigeration system has the following problems.

That is, when the outside air temperature is high, the amount of heat of the hot gas from the compressor is effectively used for defrosting, and the temperature of the suction gas is rapidly increased. As shown in FIG. operation is completed (see time T _2, the solid curve in the figure). However, when the outside air temperature is low, the amount of heat released from the refrigerant circuit to the outside air is large,
The amount of heat that can be used for defrost per unit time decreases, and the rate of rise of the intake gas temperature decreases. Therefore,
The defrost operation time becomes longer (the time indicated by the broken curve in the figure)
T reference _3).

Also, when the outside air temperature is low, the amount of water generated in the refrigerator is small and ventilation is not performed, so that the amount of frost is generally small. Nevertheless, the defrost operation is performed for a long time as described above. Therefore, the amount of heat supplied during the defrost operation is consumed not only for melting frost on the evaporator and the drain pan, but also for raising the temperature of the frame of the in-compartment unit. In other words, not only extra energy is consumed in the defrost operation, but also energy for cooling the frame or the like whose temperature has risen is further required, resulting in an increase in power consumption. In addition, an excessive rise in the internal temperature causes an increase in the cargo temperature.

The present invention has been made in view of such a point, and an object of the present invention is to reduce the temperature of the intake gas even when the defrost operation time reaches a time that gives a sufficient amount of heat to melt the frost of the evaporator. If the set temperature is not reached, change the set temperature value to a lower value to prevent unnecessary defrost operation, thereby reducing power consumption and preventing the cargo item temperature from rising excessively. It is in.

(Means for Solving the Problems) In order to achieve the above object, as shown in FIG. 1 (excluding a broken line portion), a first solution is a compressor (1), a condenser (3), It is assumed that the refrigerating apparatus includes a refrigerating circuit (9) in which a mechanism (5) and an evaporator (6) are sequentially connected.

As the operation control device of the refrigeration system, the suction gas temperature detecting means (Th5) for detecting the temperature of the suction gas to the compressor (1) and the suction gas temperature detecting means (Th5) during the defrost operation. The defrost operation control means (5) controls the evaporator (6) to perform the defrost operation until the suction gas temperature to be taken becomes higher than the set temperature.
1) is provided.

Further, a timer is set to time up when a predetermined time elapses after the defrost operation is started, and the timer is changed so that the set temperature is lowered only when the time of the suction gas temperature exceeds the set temperature earlier. Changing means (52) is provided.

As shown in FIG. 1 (including the broken line portion), the second solution means in addition to the first solution means, instructs a defrost operation every time a fixed time of the refrigeration mode in-range elapses. Signal output means (53) for outputting a command signal is provided.

(Operation) With the above configuration, in the invention of claim (1), when a defrost command signal is received during operation, the defrost operation is performed by the defrost operation control means (51). In this defrost operation, frost formation on the evaporator (6) is removed until the intake gas temperature detected by the intake gas temperature detection means (Th5) reaches the set temperature. The timer starts counting at the same time as the start of the defrost operation.

Then, the changing means (52) changes the set temperature to be lower only when the timer expires earlier than when the intake gas temperature exceeds the set temperature. As described above, by reducing the set temperature, the defrost operation time is reduced to a necessary minimum. Therefore, a situation in which the defrost operation is not completed even though the defrost operation sufficient to melt the frost of the evaporator (6) is avoided. As a result, an excessive rise in the cargo temperature is prevented, and power consumption is reduced.

(Example) Hereinafter, an example of the present invention will be described with reference to FIG. 2 and subsequent drawings.

FIG. 2 shows a refrigerant piping system of a refrigeration apparatus provided in a refrigeration container or the like according to an embodiment of the present invention. (1) is a compressor, (3) is a condenser provided with a fan (3a),
(4) is a receiver, (5) is an electronic expansion valve as a decompression mechanism for decompressing a refrigerant, (6) is an evaporator provided with a fan (6a) and arranged in a freezer, and (7) is the compressor described above. (1)
This is an accumulator for removing a liquid component in the refrigerant sucked into the refrigerant. These devices are connected by a refrigerant pipe (8) so that the refrigerant can circulate, and constitute a refrigeration circuit (9). The refrigeration circuit (9) transfers the cold heat obtained by heat exchange with the outside air in the condenser (3) and discharges it into the refrigerator by the evaporator (6).

(2) is a three-way proportional valve interposed in the refrigerant pipe (8) between the compressor (1) and the condenser (3);
(10) has one end connected to the three-way proportional valve (2), and the other end bypassing the condenser (3), the receiver (4) and the electronic expansion valve (5), and being upstream of the evaporator (6). This is a hot gas bypass connected to the liquid line (8a). The hot gas bypass passage (10) is a drain pan heater section (11)
It has. That is, when the evaporator (6) is frosted, a part of the hot gas discharged from the compressor (1) is bypassed to the hot gas bypass path (10) by adjusting the three-way proportional valve (2), The drain pan heater section (11) is heated. Thereby, frost formation on the evaporator (6) and the drain pan (not shown) is melted.

Further, sensors are arranged in the present apparatus. (HP
S) is a high-pressure sensor that detects the high-pressure side pressure, (Th1) is a liquid tube sensor that detects the liquid tube temperature of the evaporator (6), and (Th2) is a gas tube that detects the gas tube temperature of the evaporator (6). Sensors,
(Th3) is disposed at the air inlet of the evaporator (6) and detects an intake air temperature, and (Th4) is disposed at the air outlet of the evaporator (6) and blows air into the refrigerator. An outlet temperature sensor for detecting the temperature, (Th5) is a suction pipe sensor disposed as a suction pipe and serving as suction gas temperature detection means for detecting a suction gas temperature t. The suction pipe sensor (Th5) is a detection unit of the defrost completion thermostat (12) for detecting the end of the defrost operation. Each of the above sensors is connected to the controller (20) by a signal line. The controller (20) controls the operation of the refrigeration system.

Here, the control contents of the controller (20) will be described based on the flowchart of FIG. FIG. 3 shows the control contents in the refrigeration mode in-range. Step S ₁
In receives a defrosting operation command signal output from the defrost timer (not shown), to start the defrost operation in step S _2, starts recounting defrost timer in step S _3. In S _4, enter the suction gas temperature t of the suction pipe sensor (Th5) detects a first set temperature t ₁ of the intake gas temperature t defrost completion thermo Step S ₅ (12)
(For example, a temperature of about 35 ° C.). In the determination in step S _5, the first set temperature t ₁ following during inhalation gas temperature t defrost completion thermo (12), the process proceeds to step S _6, the count of the timer starts to count at step S ₃ T is a predetermined time T ₁ (for example, a value of about 30 minutes, the product of the integral input of the compressor (1) and the defrost efficiency when the outside air temperature is −10 ° C. becomes the heat quantity required for defrosting frost and the like. (Set as time). Count T is up exceeds the predetermined time T ₁ repeats the control of the step S _4, S _5. When the count T is determined in the suction gas temperature t in step S ₅ even after the lapse of a predetermined time T ₁ does not exceed the first predetermined temperature t _1, the process proceeds to step S _7, setting of the defrost completion thermo (12) The temperature is set to a second set temperature t ₂ lower than the first set temperature t _1.
(For example, a value of about 20 ° C.). Detecting the intake gas temperature t in step S _8, it is determined whether the suction gas temperature t is higher than the second set temperature t ₂ in step S _9. In other words, than the timeout of the timer, as early as is better suction gas temperature exceeds the first set temperature t ₁ without changing the set temperature value, than the intake gas temperature exceeds the first set temperature t _1, the set temperature value as early as the timer timeout of the change to the second set temperature t ₂ for comparing the set temperature t ₂ of the suction gas temperature t Toko.

Performing the above control, or Step S ₅ discriminated by the suction gas temperature t in is higher than the first set temperature t _1, high suction gas temperature t in the determination in step S ₉ than the second set temperature t ₂ comes to, frosted evaporator (6) it determines that had melted, the process proceeds to step S _10, and ends the defrost operation.

In the above flow, the control of step S _2, S ₅ and S _10, until the suction gas temperature t is higher than the set temperature, the defrosting operation control means for controlling to perform defrosting operation of the evaporator (6) (51) is configured. The control at step S _7, the intake gas at the time when the predetermined time T ₁ after the start of the defrost operation has elapsed temperature t is set temperature
When t ₁ below, i.e., when the early time of the timer than the intake gas temperature t exceeds the set temperature t _1, the set temperature of the defrost operation control means (51) (the second set temperature t ₂ A) changing means (52) for changing the value to a lower value is provided.

Further, according to the invention of claim (2), in step S _1, it is the signal output means for outputting a command signal for commanding (53) is adapted to the defrosting operation every time the predetermined time of freezing mode-range has elapsed I have.

Therefore, in the invention of claim (1), upon receiving the defrost command signal during operation of the refrigeration system, the defrost operation control means (51) detects the suction by the suction pipe sensor (suction gas temperature detection means) (Th5). Until the gas temperature t reaches the set temperature t ₁ , the opening degree of the three-way proportional valve (2) is adjusted so that the hot gas discharged from the compressor (1) is supplied to the drain pan heater of the hot gas bypass path (10). A defrost operation for defrosting the frost on the evaporator (6) is performed by bypassing the unit (11).

In this case, as shown in FIG. 4, when the outside air temperature is high, the rise of the intake gas temperature t is also rapid, and the defrost operation ends in a relatively short time T ₂ (for example, about 30 minutes) from the start of the defrost operation. (See the solid curve in the figure). However, when the outside air temperature is low, the amount of heat released to the outside air in the condenser (3) is large, so that the amount of heat that can be used for defrost per unit time decreases, and the rising speed of the intake gas temperature t does not decrease. Therefore, defrosting operation time is very longer as time T ₃ of the dashed curve in FIG. (For example, about 90 minutes time). When the outside air temperature is low, the amount of water in the refrigerator is relatively small, and it is not necessary to perform the defrost operation for a long time. Therefore, the defrost operation is performed for an unnecessarily long time, which not only increases the power required for the defrost operation, but also causes the evaporator (6) and the drain pan heater (11) to melt the frost. Since the temperature of the frame or the like is increased, extra power is required for cooling the frame and the like, which may cause an increase in power consumption.

In contrast, in the present invention, the suction gas temperature t than exceeds the first set temperature t _1, is changed to lower the set temperature value as early as the time-up of the defrost timer to the second set temperature t _2. For this reason, the defrost operation time can be reduced to a necessary minimum (for example, until time T4 in FIG. ₄ ). Therefore, it is possible to prevent the cargo item temperature from excessively rising and to reduce power consumption.

The predetermined time T _1, the outside air temperature as -10 ° C.,
The product of the integral input of the compressor (1) and the defrost efficiency is sufficient to melt the frost and ice of the evaporator (6) and to be larger than the amount of heat required to raise the temperature of the casing and the like at that time. It is set as time. For this reason, there is no possibility that the defrosting of the evaporator (6) becomes insufficient due to the shortening of the defrost operation time.

In the invention of claim (2), in the invention of claim (1), the signal output means (53) outputs a defrost operation command signal at regular intervals of the refrigeration mode in-range. In the operation in such a refrigeration mode in-range, the amount of generated moisture is small and the amount of frost is small particularly because the cargo item is frozen. Also in such a case, the defrosting operation time according to the invention of the above claim (1) can be shortened, so that the remarkable effect of the invention of the claim (1) can be obtained.

(Effect of the Invention) As described above, according to the invention of claim (1),
In a refrigeration system that performs defrost operation, the defrost operation is performed until the intake gas temperature reaches a predetermined set temperature, but the set temperature value is changed to a lower value only when the timer expires earlier than when the intake gas temperature exceeds the set temperature. As a result, the defrost operation time can be shortened, so that the power consumption can be reduced and the temperature of the space provided with the evaporator can be prevented from excessively rising.

According to the invention of claim (2), in the invention of claim (1), the defrost operation is performed every time the holding time in the refrigeration mode in-range elapses a predetermined time, so that the amount of generated water is small. In the refrigeration mode in-range where the amount of frost is small, the defrost operation according to the invention of the above-mentioned claim (1) can be shortened, so that the effect of the invention of the above-mentioned claim (1) can be more remarkably exhibited. .

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of the present invention. Fig. 2 and subsequent figures show an embodiment of the present invention, Fig. 2 is a refrigerant piping system diagram showing a configuration of a refrigeration system, Fig. 3 is a flowchart diagram showing control contents according to the invention of claim (1), and Figs. The figure is an explanatory diagram showing the effect of the present invention. DESCRIPTION OF SYMBOLS 1 ... Compressor 3 ... Condenser 5 ... Electronic expansion valve (decompression mechanism) 6 ... Evaporator 9 ... Refrigeration circuit 51 ... Defrost operation control means 52 ... Change means 53 ... Signal output means Th5 ... Suction pipe sensor (suction gas temperature detection means)

Continued on the front page (56) References Japanese Utility Model Showa 57-42374 (JP, U) Japanese Utility Model Showa 55-108371 (JP, U) Japanese Utility Model Showa 60-30985 (JP, U) (58) Fields surveyed (Int) .Cl. ⁷ , DB name) F25B 47/02 F25D 21/00-21/02 F25D 21/06-21/12

Claims (2)

(57) [Claims] 1. A refrigerating apparatus having a refrigerating circuit (9) in which a compressor (1), a condenser (3), a pressure reducing mechanism (5) and an evaporator (6) are sequentially connected. 1) a suction gas temperature detecting means (Th5) for detecting the temperature of the suction gas to the suction port, and a defrost operation until the suction gas temperature detected by the suction gas temperature detecting means (Th5) becomes higher than a set temperature. During the above evaporator (6)
A defrost operation control means (51) for controlling to perform the defrost operation, and a timer that times up when a predetermined time has elapsed after the start of the defrost operation. And a changing means (52) for changing the set temperature to be lower only when the time-up of the timer is early. 2. The apparatus according to claim 1, further comprising a signal output means (53) for outputting a command signal for instructing a defrost operation every time a predetermined time of the refrigeration mode in-range elapses. Operation control device for refrigeration equipment.