JP2010203641A - Refrigerating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To take measures against frequent start/stop of a compressor due to hunting. <P>SOLUTION: This refrigerating device includes a refrigerant circuit (10) having the inverter type compressor (31) with variable capacity and a temperature sensing type expansion valve (22) and performs a vapor compression type refrigerating cycle by circulating a refrigerant in the refrigerant circuit (10). The refrigerating device further includes a hunting determination part (33c) for determining whether the temperature sensing type expansion valve (22) is in the hunting state. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a refrigeration apparatus that performs a vapor compression refrigeration cycle by circulating a refrigerant.

  There is a refrigeration apparatus that performs a refrigeration cycle, for example, a refrigerator (or a freezer) that is installed in a store or the like and stores food or the like (see, for example, Patent Document 1).

The refrigeration apparatus of Patent Document 1 includes an outdoor unit having a compressor and an outdoor heat exchanger (heat source side heat exchanger), a refrigeration heat exchanger (a use side heat exchanger of the first system), and an expansion mechanism. A refrigeration unit (first usage side unit), a refrigeration unit (second usage side unit), a refrigeration heat exchanger (second usage side heat exchanger), and an expansion mechanism. Yes. In addition, this refrigeration apparatus includes, in its outdoor unit, a compressor whose electric motor is inverter-controlled and whose capacity is variable stepwise or continuously, that is, a so-called inverter-type compressor whose operating frequency is controlled by an inverter circuit. In this refrigeration apparatus, a temperature-sensitive expansion valve is used as an expansion mechanism in the refrigerant circuit.
JP 2003-004318 A

  By the way, the temperature-sensitive expansion valve of a refrigerator installed in a store or the like generally adjusts the degree of static superheat when the freezer is installed in a store or the like. However, in such a refrigerator, the temperature-sensitive expansion valve is often used in the state where the static superheat degree is set at the time of installation. Depending on the internal load and the size of the safety factor when selecting the refrigerator model, the setting may not match the actual situation (the load of the refrigeration apparatus).

  For example, if the inverter compressor is operated at a low frequency when the setting of the degree of static superheat is inappropriate, the capacity of the temperature-sensitive expansion valve is excessive with respect to the flow rate of the refrigerant (that is, the throttle action cannot be sufficiently exerted) State). When the capacity is excessive, a phenomenon (hunting) in which the degree of superheat fluctuates easily occurs, and as a result, the low-pressure pressure in the refrigerant circuit also fluctuates.

  Moreover, the capacity adjustment range of the refrigerator equipped with the inverter compressor has a change range of about 20 to 100%. On the other hand, since the temperature adjustment type expansion valve generally has a capacity adjustment range of about 60 to 120%, there is an operation range that cannot be controlled by the combination of the inverter refrigerator and the temperature detection type expansion valve. In addition, when selecting a refrigerator model based on the internal load, the safety factor varies depending on the size of the load fluctuation in the internal storage and the usage situation. For example, in refrigeration (such as refrigerators where the internal temperature is -5 ° C or lower), the safety factor for the load is increased to ensure the quality of stored items, so the inverter compressor is low even in the intermediate and winter seasons. Controlled by operating frequency, hunting is encouraged.

  In a general refrigeration system, the compressor is stopped when the low pressure decreases to a value below a certain level (referred to as a low pressure cut value). Therefore, when hunting occurs, the compressor starts and stops frequently. In particular, in a refrigeration system in which the use side is cooled (for example, the refrigerator having an internal temperature of −5 ° C. or lower), the compressor is frequently stopped because the difference between the target low pressure value and the low pressure cut value is small. It is thought that it is easy to be made.

  Thus, even if the compressor starts and stops frequently, the internal temperature becomes higher than the set temperature in this state, so the operating frequency is increased and eventually the internal temperature becomes the set temperature. In other words, this hunting is generally difficult to notice as long as it can be cooled to the set temperature, and may not cause poor quality of stored items (such as food), so there is no inconvenience in use. It is done.

  However, when the compressor starts and stops frequently, the deterioration of the compressor proceeds. In addition, power consumption is increased due to frequent increase in the operating frequency.

  The present invention has been made paying attention to the above-described problem, and an object of the present invention is to be able to take measures to prevent frequent start / stop of the compressor due to hunting.

In order to solve the above problems, the first invention is
A refrigerant circuit (10) including a compressor (31) having a variable capacity and a temperature-sensitive expansion valve (22) is provided, and the refrigerant is circulated in the refrigerant circuit (10) to perform a vapor compression refrigeration cycle. A refrigeration apparatus to perform,
A hunting determination unit (33c) for determining whether or not the temperature-sensitive expansion valve (22) is in a hunting state is provided.

  With this configuration, a vapor compression refrigeration cycle is performed in the refrigerant circuit (10). At this time, the hunting determination unit (33c) determines whether or not the temperature-sensitive expansion valve (22) is in the hunting state. The If the state of the temperature-sensitive expansion valve (22) can be determined in this way, it is possible to take predetermined measures so that the compressor (31) does not frequently start and stop.

In addition, the second invention,
In the refrigeration apparatus of the first invention,
A low pressure sensor (34) for detecting a low pressure of the refrigerant circuit (10);
When the amplitude of the low pressure detected by the low pressure sensor (34) is greater than or equal to a predetermined threshold amplitude (B), the temperature sensing expansion valve (22) is in the hunting state. It is characterized by judging.

  With this configuration, the determination in the hunting determination unit (33c) is made by comparing the amplitude of the low pressure detected by the low pressure sensor (34) with a predetermined threshold amplitude (B). That is, it is possible to easily determine whether or not the temperature-sensitive expansion valve (22) is in the hunting state.

In addition, the third invention,
In the refrigeration apparatus of the first invention,
A low pressure sensor (34) for detecting a low pressure of the refrigerant circuit (10);
When the amplitude of the low pressure detected by the low pressure sensor (34) is not less than a predetermined amplitude for a predetermined period or longer, the hunting determination unit (33c) Is determined to be in the hunting state.

  With this configuration, the hunting determination unit (33c) determines the hunting state based on the period in which the low pressure amplitude greater than or equal to the predetermined amplitude continues. Therefore, for example, when the compressor (31) is operated with low capacity and the low pressure amplitude is relatively small, it is possible to accurately determine whether or not the temperature-sensitive expansion valve (22) is in the hunting state. become.

In addition, the fourth invention is
In any one of the first to third aspects of the refrigeration apparatus,
The hunting determination unit (33c) performs the determination when the capacity of the compressor (31) is controlled to be equal to or less than a predetermined ratio of the rated capacity of the temperature-sensitive expansion valve (22). Features.

  With this configuration, since it is determined whether or not the hunting state is established based on the relationship between the capacity of the compressor (31) and the rated capacity of the temperature-sensitive expansion valve (22), the determination is performed more reliably. It becomes possible.

In addition, the fifth invention,
In the refrigeration apparatus of the fourth invention,
A storage unit (33b) for storing information indicating the rated capacity of the temperature-sensitive expansion valve (22) or information indicating the degree of static superheat in the temperature-sensitive expansion valve (22);
The hunting determination unit (33c) estimates the capability of the temperature-sensitive expansion valve (22) based on information stored in the storage unit (33b).

  With this configuration, information indicating the capability of the temperature-sensitive expansion valve (22) or information indicating the set value of the static superheat degree in the temperature-sensitive expansion valve (22) is stored in the storage unit (33b), that is, in the refrigeration apparatus. Therefore, it is possible to accurately grasp the ability of the temperature-sensitive expansion valve (22). Therefore, it is possible to easily determine whether or not the temperature-sensitive expansion valve (22) is in the hunting state.

In addition, the sixth invention,
In any one of the first to fifth aspects of the refrigeration apparatus,
The display device further includes a display unit (33d) for displaying a determination result of the hunting determination unit (33c).

  With this configuration, it is possible to prompt the user to adjust the temperature-sensitive expansion valve (22) by displaying the determination result of the hunting determination unit (33c) on the display unit (33d).

In addition, the seventh invention,
In any one of the first to sixth aspects of the refrigeration apparatus,
A compressor control unit (33a) for stopping the compressor (31) for a predetermined period when the hunting determination unit (33c) determines that the temperature-sensitive expansion valve (22) is in a hunting state; It is characterized by that.

  With this configuration, the compressor (31) is stopped for a certain period when the temperature-sensitive expansion valve (22) is in the hunting state. That is, frequent occurrence of the start / stop of the compressor (31) is prevented during a period in which hunting is occurring. Then, if the compressor (31) is stopped for a certain period in this way, the opening degree of the temperature-sensitive expansion valve (22) is adjusted in the direction in which the flow rate of the refrigerant increases, and then the compressor (31) When the operation is resumed, it is possible to prevent the hunting state.

  According to the first invention, since it becomes possible to take predetermined measures so that the compressor (31) does not frequently start and stop, it is possible to extend the life of the compressor (31). Become.

  Further, according to the second invention, since it becomes possible to easily determine whether or not the temperature-sensitive expansion valve (22) is in the hunting state, it is possible to prevent frequent start / stop of the compressor (31). It becomes possible to carry out easily. Since the low pressure sensor (34) normally provided in the refrigeration apparatus can be used for the determination of the hunting state, the determination can be made without adding a special apparatus.

  Moreover, according to the third invention, for example, when the low pressure amplitude is relatively small, it is possible to accurately determine whether or not the temperature-sensitive expansion valve (22) is in the hunting state. It becomes possible to more reliably prevent frequent start / stop of the compressor (31).

  Further, according to the fourth aspect of the invention, it is more reliably determined whether or not the temperature-sensitive expansion valve (22) is in the hunting state. It becomes possible to do.

  Further, according to the fifth aspect, since it is possible to easily determine whether or not the hunting state is present, it is possible to more easily prevent the compressor (31) from being frequently started and stopped. Become.

  Further, according to the sixth aspect of the invention, it is possible to prompt the user to adjust the temperature-sensitive expansion valve (22), so that the user can adjust the degree of static superheat of the temperature-sensitive expansion valve (22), for example. It is possible to take necessary measures to prevent frequent start / stop of the compressor (31) such as adjustment.

  In addition, according to the seventh aspect, since frequent occurrence of the start / stop of the compressor (31) is prevented, the life of the compressor (31) can be extended.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

"Overview"
FIG. 1 is a piping diagram of a refrigerant circuit (10) in a refrigeration apparatus (1) according to an embodiment of the present invention. This refrigeration apparatus (1) performs a vapor compression refrigeration cycle so that the user side is cooled. Specifically, this refrigeration apparatus (1) is realized, for example, as a freezer (or a refrigerator) that is installed in a store or the like and stores food products or the like, and the internal temperature is cooled to, for example, −5 ° C. or lower.

<< Overall configuration of refrigeration system (1) >>
As shown in FIG. 1, the refrigeration apparatus (1) includes an indoor unit (20) installed indoors and an outdoor unit (30) installed outdoor. The indoor unit (20) and the outdoor unit (30) are connected to each other via a first connection pipe (11) and a second connection pipe (12), and a refrigerant circulates to form a vapor compression refrigeration cycle. The refrigerant circuit (10) for performing the above is configured.

<Indoor unit (20)>
The indoor unit (20) includes a use side heat exchanger (21) and a temperature-sensitive expansion valve (22), and cools the air in the refrigerator (use side).

  The use side heat exchanger (21) is a cross-fin type fin-and-tube heat exchanger, and in this use side heat exchanger (21), the refrigerant and the use side air (air in the refrigerator) Heat exchange between the two. An indoor fan (not shown) is provided in the vicinity of the use side heat exchanger (21). The use side air is sent to the use side heat exchanger (21) by the indoor fan.

  The temperature-sensitive expansion valve (22) is a so-called automatic temperature expansion valve whose opening degree is adjusted according to the detected temperature of the temperature-sensitive cylinder (22a). Specifically, when the detected temperature of the temperature sensing cylinder (22a) rises, the temperature sensitive expansion valve (22) is adjusted to open, and when the detected temperature falls, the temperature sensitive expansion valve (22) closes. Adjusted to The temperature-sensitive expansion valve (22) is provided with a static superheat degree adjusting mechanism. The temperature-sensitive expansion valve (22) has its refrigerant inflow side connected to the liquid side end of the heat source side heat exchanger (32) via the second connection pipe (12), and the refrigerant outflow side is used. It is connected to the liquid side end of the side heat exchanger (21). The temperature sensing cylinder (22a) is disposed at the gas side end on the refrigerant outflow side of the use side heat exchanger (21), and is connected to the temperature sensing type expansion valve (22) by a capillary tube.

<Outdoor unit (30)>
The outdoor unit (30) includes an inverter compressor (31), a heat source side heat exchanger (32), a control device (33), and a low pressure sensor (34) (abbreviated as LP in the figure).

  The inverter type compressor (31) is configured by a positive displacement compressor such as a scroll compressor, for example. The inverter type compressor (31) is supplied with electric power through an inverter circuit, and the operating frequency is controlled by the inverter circuit so that the operating capacity (capacity) is variable. The inverter circuit of this embodiment changes this operating frequency in the range of 19 Hz to 109 Hz. The discharge port of the inverter compressor (31) is connected to the gas side end of the heat source side heat exchanger (32) via a refrigerant pipe. The suction port of the inverter compressor (31) is connected to the indoor unit (20) via the first connection pipe (11).

  The heat source side heat exchanger (32) is a cross fin type fin-and-tube heat exchanger, and in this heat source side heat exchanger (32), the refrigerant and the heat source side air (outdoor air) Heat exchange is performed between them. An outdoor fan (not shown) is provided in the vicinity of the heat source side heat exchanger (32). Outdoor air is sent to the heat source side heat exchanger (32) by the outdoor fan. The liquid source end of the heat source side heat exchanger (32) is connected to the indoor unit (20) via the second connection pipe (12).

  The low pressure sensor (34) detects the low pressure of the refrigerant circuit (10) on the suction port side of the inverter compressor (31). The detection value (value indicating the low pressure) of the low pressure sensor (34) is input to the control device (33).

-Control device (33)-
The control device (33) controls the inverter compressor (31) and determines the hunting state of the temperature-sensitive expansion valve (22). The control device (33) in this example includes a compressor control unit (33a), a storage unit (33b), a hunting determination unit (33c), and a display unit (33d).

  The compressor controller (33a) controls the operating frequency of the inverter compressor (31) by controlling the inverter circuit and the like.

  The storage unit (33b) stores information indicating the static superheat degree of the temperature-sensitive expansion valve (22) (specifically, the static superheat degree set at the time of shipment of the temperature-sensitive expansion valve (22)). It has become. The storage unit (33b) can be configured using, for example, a rewritable nonvolatile memory.

  The hunting determination unit (33c) determines whether or not the temperature-sensitive expansion valve (22) is in the hunting state. In this refrigeration system (1), when the capacity of the inverter compressor (31) is controlled to be equal to or less than a predetermined ratio (for example, 50%) of the rated capacity of the temperature-sensitive expansion valve (22), hunting determination The unit (33c) is configured to execute the determination. At this time, the hunting determination unit (33c) estimates the capacity of the inverter compressor (31) from the refrigerant pressure and temperature during the cooling operation, the current of the inverter circuit, the operation frequency, and the like. Further, the hunting determination unit (33c) calculates the temperature sensitivity based on the static superheat degree of the temperature-sensitive expansion valve (22) stored in the storage unit (33b) and the high and low pressure data in the refrigerant circuit (10). Estimate the capacity of the expansion valve (22).

  In the refrigeration apparatus (1), the hunting determination unit (33c) is configured to detect the temperature-sensitive expansion valve when the low-pressure pressure amplitude (low-pressure pressure amplitude) detected by the low-pressure sensor (34) is equal to or greater than a predetermined threshold. (22) is determined to be in the hunting state. In the present embodiment, the threshold value is such that both the outside air temperature and the inside temperature are high, the operating frequency of the inverter compressor (31) is high, and the refrigeration function is 80% of the capacity of the temperature sensitive expansion valve (22). The amplitude (A) MPa of the low-pressure pressure in the above case (for example, when operating in the summer or when the operation frequency of the inverter-type compressor (31) is intentionally increased during trial operation) is stored, and this amplitude ( A) An amplitude larger than MPa (for example, an amplitude three times the amplitude (A) MPa (hereinafter referred to as a threshold amplitude (B)).

  Further, when the low pressure amplitude is smaller than the threshold amplitude (B) MPa, the hunting judgment section (33c) judges the hunting state based on the period during which the low pressure amplitude greater than or equal to the predetermined amplitude continues. Specifically, the hunting determination unit (33c) monitors the low-pressure pressure amplitude, and continues for a certain period (for example, 30 minutes or more) and continues with a predetermined amplitude (for example, 1.5 × amplitude (A) MPa). If it is determined that the temperature sensitive expansion valve (22) is in the hunting state. In this way, whether or not the temperature-sensitive expansion valve (22) is in the hunting state when the operating frequency of the inverter compressor (31) is kept low and the low pressure amplitude is relatively small. Can be determined more accurately.

  The display unit (33d) displays the determination result of the hunting determination unit (33c). Specifically, when the hunting determination unit (33c) determines that the temperature-sensitive expansion valve (22) is in the hunting state, the display unit (33d) displays that fact and the optimum degree of static superheat. This display prompts the user to adjust the temperature-sensitive expansion valve (22). In addition, in FIG. 1, although this display part (33d) is provided in the outdoor unit (30), you may provide in a remote controller etc. for a user to operate freezing apparatus (1), for example.

<< Operation of refrigeration system (1) >>
When the inverter compressor (31) is put into an operating state, the refrigerant circulates in the refrigerant circuit (10) in the direction indicated by the solid line arrow in FIG. Specifically, the refrigerant discharged from the inverter compressor (31) flows into the heat source side heat exchanger (32), and the heat source side heat exchanger (32) converts the outdoor air taken in by the outdoor fan. It dissipates heat and condenses. The condensed refrigerant flows into the indoor unit (20) through the second connection pipe (12).

  For example, when the temperature in the refrigerator is higher than the set temperature, that is, when the heat load is large, the operation frequency is increased by the inverter circuit, and is set to, for example, the maximum operation frequency (for example, 109 Hz). On the other hand, when the heat load increases, the temperature of the temperature sensitive cylinder (22a) rises, and as a result, the temperature sensitive expansion valve (22) is adjusted in the opening direction.

  As described above, the refrigerant flowing into the indoor unit (20) from the heat source side heat exchanger (32) is expanded by the temperature-sensitive expansion valve (22). The refrigerant expanded by the temperature-sensitive expansion valve (22) is introduced into the use side heat exchanger (21) and absorbs heat from the air in the refrigerator (use side) in the use side heat exchanger (21). Evaporate. Thereby, the air in a refrigerator is cooled. Thereafter, the evaporated refrigerant is sucked into the inverter compressor (31) through the first connection pipe (11) and compressed. Then, the compressed refrigerant flows into the heat source side heat exchanger (32).

  When the air in the refrigerator is thus cooled and the temperature of the air gradually approaches the set temperature, the heat load is gradually reduced and the operation frequency is gradually lowered. As the heat load decreases, the temperature of the temperature sensing cylinder (22a) decreases, and as a result, the temperature sensing expansion valve (22) is adjusted in the closing direction, and the gas side of the use side heat exchanger (21) is adjusted. The opening degree depends on the degree of superheat at the end.

<< Judgment of hunting in refrigeration system (1) >>
FIG. 2 is a flowchart showing the hunting determination operation and the operation when it is determined that the hunting state is in the refrigeration apparatus (1).

  During operation of the refrigeration system (1), the hunting determination unit (33c) estimates the capacity of the inverter compressor (31) and the capacity of the temperature-sensitive expansion valve (22) in step (S01). Specifically, the pressure and temperature of the refrigerant, the current of the inverter circuit, the operation frequency, and the like (hereinafter, these data are collectively referred to as operation data) are acquired. And the capability of an inverter type compressor (31) is estimated from these operation data. In addition, the hunting determination unit (33c) determines the capability of the temperature-sensitive expansion valve (22), the degree of static superheat set in the temperature-sensitive expansion valve (22), and the high and low pressures in the refrigerant circuit (10). From the data of And if the capability of an inverter type compressor (31) and a temperature sensing type expansion valve (22) will be found, a hunting judgment part (33c) will perform processing after Step (S02).

  First, in step (S02), it is determined whether or not the capacity of the inverter compressor (31) is controlled to be equal to or less than a predetermined ratio (50% in this example) of the rated capacity of the temperature-sensitive expansion valve (22). To do. If it is 50% or less, the process proceeds to step (S03).

  In step (S03), it is determined whether or not the temperature-sensitive expansion valve (22) is in the hunting state. That is, in this refrigeration system (1), when the capacity of the inverter compressor (31) is controlled to be equal to or less than a predetermined ratio of the rated capacity of the temperature-sensitive expansion valve (22), the temperature-sensitive expansion valve ( The hunting determination unit (33c) executes the determination of whether or not 22) is in the hunting state.

  In this step (S03), the hunting determination unit (33c) determines whether or not the low pressure pressure amplitude detected by the low pressure sensor (34) is greater than or equal to the threshold amplitude (B) MPa. As a result, if the temperature-sensitive expansion valve (22) is in the hunting state when the low-pressure pressure amplitude is greater than or equal to the threshold amplitude (B) MPa, the hunting determination unit (33c) determines and performs the processing in step (S04). Transition. When the low pressure amplitude is smaller than the threshold amplitude (B) MPa, the process proceeds to step (S07).

  In step (S04), the hunting determination unit (33c) checks whether or not the low pressure cut due to a factor other than the thermo-off has been repeated a predetermined number of times (5 times in this example). As a result of the confirmation, if it has been repeated five times or more, the process proceeds to step (S05), and otherwise, the process proceeds to step (S06).

  For example, when the process proceeds to step (S05), the hunting determination unit (33c) displays on the display unit (33d) that the temperature-sensitive expansion valve (22) is in the hunting state and the optimum degree of static superheat. . Thereby, it becomes possible to prompt the user to adjust the temperature-sensitive expansion valve (22) (for example, adjustment of the degree of static superheat). On the other hand, when the process proceeds to step (S06), the hunting determination unit (33c) increases the operating frequency of the compressor control unit (33a), for example, and the capacity of the inverter compressor (31) is increased. Control is made so that it is 65% or more of the rated capacity of the temperature-sensitive expansion valve (22). Thereby, the refrigerant | coolant flow rate in a temperature sensitive type expansion valve (22) increases.

  If the result of determination in step (S03) is that the process proceeds to step (S07), the hunting determination unit (33c) determines that the amplitude of the low-pressure pressure in the step (S07) In this example, it is confirmed whether or not it has continued at an amplitude greater than or equal to a predetermined value (in this example, 1.5 × amplitude (A) MPa). If the amplitude of 1.5 × amplitude (A) MPa or more continues for 30 minutes or more, the process proceeds to step (S08), and in other cases, the process returns to step (S02).

  In step (S08), the hunting determination unit (33c) determines whether or not there is a low pressure cut due to a factor other than the thermo-off, and if there is a low-pressure cut due to a factor other than the thermo-off, the process proceeds to the process of step (S06). In other cases, the process returns to step (S02).

<< Effect in this embodiment >>
As described above, in the present embodiment, the hunting determination unit (33c) determines whether or not the temperature-sensitive expansion valve (22) is in the hunting state. If the state of the temperature-sensitive expansion valve (22) can be determined in this way, it is possible to take predetermined measures so that the inverter-type compressor (31) does not frequently start and stop. And if such a measure is taken, it becomes possible to extend the lifetime of an inverter type compressor (31). In this example, the user adjusts the degree of static superheating of the temperature-sensitive expansion valve (22), for example, according to the display on the display unit (33d), thereby reducing the frequent occurrence of the inverter compressor (31). it can. And it becomes possible to extend the lifetime of an inverter type compressor (31) by reducing the frequent occurrence of start / stop.

  It is also possible to prevent an increase in power consumption due to frequent increases in the operating frequency.

  In addition, if the temperature-sensitive expansion valve (22) is not able to exert a throttling effect, a phenomenon (liquid return) occurs in which the liquid refrigerant returns to the inverter compressor (31), resulting in dilution of the lubricating oil. Although this leads to so-called liquid compression, this embodiment can also prevent such a phenomenon.

<< Modification of this embodiment >>
<1> Information used for estimating the capability of the temperature-sensitive expansion valve (22) (in the above example, the degree of static superheat) is an example. In addition, for example, the model and rated capacity of the temperature-sensitive expansion valve (22) may be stored in the storage unit (33b) and used.

  <2> The display on the display unit (33d) described as a measure to be taken in the hunting state is also an example. In addition, for example, the inverter compressor (31) may be stopped for a certain period by the compressor controller (33a).

  The present invention is useful as a refrigeration apparatus that performs a vapor compression refrigeration cycle by circulating a refrigerant.

It is a piping system diagram of the refrigerant circuit (10) in the refrigeration apparatus (1) according to the embodiment of the present invention. It is a flowchart which shows the operation | movement when it is judged as the hunting judgment operation | movement and hunting state in a freezing apparatus (1).

DESCRIPTION OF SYMBOLS 1 Refrigeration apparatus 10 Refrigerant circuit 22 Temperature sensitive expansion valve 31 Inverter type compressor 33a Compressor control part 33b Memory | storage part 33c Hunting judgment part 33d Display part 34 Low pressure sensor

Claims (7)

A refrigerant circuit (10) including a compressor (31) having a variable capacity and a temperature-sensitive expansion valve (22) is provided, and the refrigerant is circulated in the refrigerant circuit (10) to perform a vapor compression refrigeration cycle. A refrigeration apparatus to perform,
A refrigeration apparatus comprising a hunting determination unit (33c) for determining whether or not the temperature-sensitive expansion valve (22) is in a hunting state. The refrigeration apparatus of claim 1,
A low pressure sensor (34) for detecting a low pressure of the refrigerant circuit (10);
When the amplitude of the low pressure detected by the low pressure sensor (34) is greater than or equal to a predetermined threshold amplitude (B), the temperature sensing expansion valve (22) is in the hunting state. A refrigeration apparatus characterized in that The refrigeration apparatus of claim 1,
A low pressure sensor (34) for detecting a low pressure of the refrigerant circuit (10);
When the amplitude of the low pressure detected by the low pressure sensor (34) is not less than a predetermined amplitude for a predetermined period or longer, the hunting determination unit (33c) Is determined to be in a hunting state. In any one freezing apparatus in any one of Claims 1-3,
The hunting determination unit (33c) performs the determination when the capacity of the compressor (31) is controlled to be equal to or less than a predetermined ratio of the rated capacity of the temperature-sensitive expansion valve (22). Refrigeration equipment characterized. The refrigeration apparatus of claim 4,
A storage unit (33b) for storing information indicating the rated capacity of the temperature-sensitive expansion valve (22) or information indicating the degree of static superheat in the temperature-sensitive expansion valve (22);
The said hunting judgment part (33c) estimates the capability of the said thermosensitive expansion valve (22) based on the information memorize | stored in the said memory | storage part (33b), The freezing apparatus characterized by the above-mentioned. In any one freezing apparatus in Claim 1-5,
The refrigeration apparatus further comprising a display unit (33d) for displaying a determination result of the hunting determination unit (33c). In any one freezing apparatus in Claim 1-6,
A compressor control unit (33a) for stopping the compressor (31) for a predetermined period when the hunting determination unit (33c) determines that the temperature-sensitive expansion valve (22) is in a hunting state; A refrigeration apparatus characterized by that.

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