JP5113776B2 - Refrigeration equipment - Google Patents

Description

  The present invention relates to a refrigeration apparatus capable of changing a thermo-on set temperature and a thermo-off set temperature.

  The refrigeration apparatus includes a refrigeration cycle configured by connecting a compressor, a condenser, an expansion valve, and an evaporator with refrigerant piping. For example, air cooled by heat exchange with the refrigerant in the evaporator (cooled) A medium that supplies a medium) to a refrigerator is known (for example, see Patent Document 1). The refrigeration apparatus described in Patent Literature 1 is roughly divided into a condensing unit including a compressor and a condenser, and a refrigerant liquid disposed in a refrigerator and provided on an evaporator, an expansion valve, and a refrigerant inlet side thereof. It is comprised with the cooler provided with the solenoid valve, and the operation control apparatus.

  The operation control device stores in advance a thermo-on set temperature and a thermo-off set temperature (where thermo-on set temperature> thermo-off set temperature), and the inside temperature, the thermo-on set temperature, and the thermo-off set temperature detected by the inside temperature sensor, And an operation command signal for the refrigeration cycle is output according to the comparison result. That is, for example, when the internal temperature becomes equal to or higher than the thermo-on set temperature, an operation start command signal is output to a condensing unit, a cooler, or the like. Thereby, the solenoid valve for refrigerant liquid is opened, and the control device of the cooler drives the blower to send air to the evaporator and circulate the air cooled by the evaporator in the refrigerator. For example, when the internal temperature becomes lower than the thermo-off set temperature, an operation stop command signal is output to a condensing unit, a cooler, or the like. As a result, the refrigerant liquid solenoid valve is closed, and the control device for the cooler stops the blower.

  By the way, when the cooling capacity of the compressor is constant, the suction pressure of the compressor increases as the internal temperature rises, and conversely when the internal temperature decreases, the intake pressure of the compressor decreases. Therefore, for the purpose of improving operating efficiency, the condensing unit control device variably controls the rotational speed (in other words, cooling capacity) of the compressor based on the suction pressure of the compressor. Specifically, the control device of the condensing unit stores in advance an upper limit set pressure, a lower limit set pressure (where upper limit set pressure> lower limit set pressure), etc., and the compressor suction detected by the suction pressure sensor The pressure is compared with the upper limit set pressure and the lower limit set pressure, and the rotational speed of the compressor is variably controlled via an inverter according to the comparison result. That is, for example, when the suction pressure is equal to or higher than the upper limit set pressure (generally, a pressure set to be smaller than the saturation pressure of the refrigerant at the thermo-on temperature), the rotation speed of the compressor is increased. For example, when the suction pressure is less than the upper limit set pressure and is equal to or higher than the lower limit set pressure (generally, a pressure set to be greater than the refrigerant saturation pressure at the thermo-off temperature), the rotation speed of the compressor is maintained. For example, when the suction pressure is less than the lower limit set pressure, the rotational speed of the compressor is decreased.

JP 2008-138879 A

  In the refrigeration apparatus described in Patent Document 1, the operation control apparatus stores the thermo-on set temperature and the thermo-off set temperature in advance, and the internal temperature, the thermo-on set temperature, and the thermo-off set temperature detected by the internal temperature sensor And a command signal for starting or stopping the operation of the refrigeration cycle is output according to the comparison result. The control device of the condensing unit stores the upper limit set pressure and the lower limit set pressure in advance, compares the compressor suction pressure detected by the suction pressure sensor with the upper limit set pressure and the lower limit set pressure, and The rotational speed of the compressor is variably controlled according to the comparison result.

  Here, there are cases where it is desired to change the setting of the target value of the internal temperature, that is, the thermo-on set temperature and the thermo-off set temperature, for example, according to the user's request. In such a case, the thermo-on set temperature and the thermo-off set temperature stored in advance in the operation control device can be changed by operating the operation unit of the operation control device (for example, a switch or a monitor). That's fine. However, at this time, along with the change of the thermo-on set temperature and the thermo-off set temperature, if the upper limit set pressure and the lower limit set pressure stored in advance in the control unit of the condensing unit are not changed to appropriate values, a setting failure occurs. There is a possibility that a cooling failure or a liquid back operation in which the liquid refrigerant returns to the compressor may occur. For this reason, it is necessary to rely on a specialist or the like, and the thermo-on set temperature and the thermo-off set temperature cannot be easily changed.

  The present invention has been made in view of the above matters, and its purpose is to reduce the set pressure so that cooling failure and liquid back operation do not occur even when the thermo-on set temperature and the thermo-off set temperature are changed. It is to provide a refrigeration apparatus that can be automatically changed.

( 1 ) In order to achieve the above object, the present invention includes a refrigeration cycle comprising a compressor, a condenser, an expansion valve, and an evaporator, a refrigerator to which a medium to be cooled cooled by the evaporator is supplied, An internal temperature sensor that detects the temperature in the refrigerator, and commands the start of operation of the refrigeration cycle when the internal temperature detected by the internal temperature sensor is equal to or higher than a thermo-on set temperature, and the internal temperature Operation control means for instructing to stop the operation of the refrigeration cycle when the inside temperature detected by the sensor becomes less than the thermo-off set temperature, and the set temperature change means capable of changing the thermo-on set temperature and the thermo-off set temperature a suction pressure sensor for detecting an intake pressure of the compressor, increasing the rotational speed of the compressor when the suction pressure sensor at the detected suction pressure is the upper limit set pressure or higher When the suction pressure detected by the suction pressure sensor is less than the upper limit set pressure and greater than or equal to the lower limit set pressure, the rotation speed of the compressor is maintained, and the suction pressure detected by the suction pressure sensor is less than the lower limit set pressure. In a refrigeration apparatus comprising compressor control means for reducing the number of revolutions of the compressor in a certain case, the set pressure is automatically changed so as to follow the internal temperature detected by the internal temperature sensor. Setting pressure changing means , an intake gas temperature sensor for detecting the intake gas temperature of the compressor, an evaporation temperature calculated from the intake pressure detected by the intake pressure sensor, and the intake gas detected by the intake gas temperature sensor A superheat degree calculating means for calculating a superheat degree that is a difference between the temperature and the evaporation temperature, and the set pressure changing means is a predetermined superheat degree calculated by the superheat degree calculating means. The temperature difference set value is corrected so as to approach the target value, and the target value of the evaporation temperature is calculated by subtracting the corrected temperature difference set value from the internal temperature detected by the internal temperature sensor. The target value of the suction pressure with the target value of the refrigerant as the saturation temperature of the refrigerant is calculated, and the upper limit set pressure and the lower limit are set so that the target value of the suction pressure is an intermediate value between the upper limit set pressure and the lower limit set pressure. Change the set pressure.

  According to the present invention, even if the thermo-on set temperature and the thermo-off set temperature are changed, the set pressure can be automatically changed so that cooling failure and liquid back operation do not occur.

It is the schematic showing the whole structure of the freezing apparatus in the 1st reference form of this invention. It is a figure which shows notionally preset temperature and preset pressure by the 1st reference form of this invention. It is a figure for demonstrating the change process of the setting pressure by the 1st reference form of this invention. It is a figure for demonstrating the change process of the upper limit setting pressure by the 2nd reference form of this invention, and a lower limit setting pressure. It is a figure for demonstrating the change process of the upper limit setting pressure by one Embodiment of this invention, and a minimum pressure.

Hereinafter, reference embodiments and embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic diagram showing the configuration of the refrigeration apparatus in the first reference embodiment of the present invention.

  In FIG. 1, the refrigeration apparatus includes a refrigeration cycle configured by connecting a compressor 1, a condenser 2, an expansion valve 3, and an evaporator 4 with refrigerant pipes, and air cooled by the evaporator 4 (cooled object). And a refrigerator 5 to which a medium) is supplied. In the refrigeration cycle, the refrigerant gas is compressed by the compressor 1 to be in a high temperature / high pressure state, cooled by the condenser 2 and condensed to become a refrigerant liquid. Thereafter, the refrigerant liquid is depressurized by the expansion valve 3 to be in a low temperature / low pressure state, evaporated by the evaporator 4 to become a low pressure refrigerant gas, and returns to the compressor 1. The evaporator 4 takes heat from the air when the refrigerant liquid evaporates, and the air thus cooled is supplied to the refrigerator 5.

  The refrigeration apparatus is roughly divided into a conditioning unit 6 including a compressor 1 and a condenser 2, a cooler 7 installed in a refrigerator 5 and including an expansion valve 3 and an evaporator 4, and an operation control apparatus 8. It is configured. In addition, although the case where one cooler 7 is installed in the refrigerator 5 is shown as an example in FIG. 1, a plurality of the coolers 7 may be installed.

  In addition to the expansion valve 3 and the evaporator 4, the cooler 7 supplies the refrigerant liquid electromagnetic valve 9 provided on the refrigerant inlet side of the expansion valve 3, and air that is sent to the evaporator 4 and cooled by the evaporator 4. And a control device (not shown) for controlling the refrigerant liquid electromagnetic valve 9 and the blower. Further, the refrigerator 1 is provided with an internal temperature sensor 10 that detects the temperature in the refrigerator 1.

  The operation control device 8 receives a detection signal from the internal temperature sensor 10 and stores the thermo-on set temperature and the thermo-off set temperature in the internal memory in advance. The internal temperature detected by the internal temperature sensor 10 is compared with the thermo-on set temperature and the thermo-off set temperature, and an operation command signal is output according to the comparison result. That is, for example, when the internal temperature becomes equal to or higher than the thermo-on set temperature, an operation start command signal is output to the condensing unit 6 and the cooler 7 via the communication line. Further, for example, when the internal temperature becomes lower than the thermo-off temperature, an operation stop command signal is output to the condensing unit 6 and the cooler 7 via the communication line.

  In response to the operation start command signal, the control device of the cooler 7 opens the refrigerant liquid electromagnetic valve 9 and drives the blower. Further, in response to the operation stop command signal, the refrigerant liquid solenoid valve 9 is closed and the blower is stopped.

  In addition to the compressor 1 and the condenser 2, the conditioning unit 6 includes a suction pressure sensor 11 that detects a suction pressure of the compressor 1, a suction gas temperature sensor 12 that detects a suction gas temperature of the compressor 1, and a compressor 1 is provided with an inverter (not shown) that variably controls the rotational speed of 1, a control device 13 that controls the compressor 1 via the inverter, and a blower (not shown) that sends air to the condenser 2. The control device 13 inputs detection signals from the suction pressure sensor 11 and the suction gas temperature sensor 12, and the upper limit set pressure (= start set pressure), the lower limit set pressure, and the stop set pressure (however, the upper limit is set in the internal memory). (Set pressure> lower limit set pressure> stop set pressure) is stored in advance. Then, the suction pressure detected by the suction pressure sensor 11 is compared with the upper limit set pressure, the lower limit set pressure, and the stop set pressure, and the compressor 1 is controlled via an inverter according to the comparison result. . As conceptually shown in FIG. 2, the upper limit set pressure is set to be lower than the refrigerant saturation pressure at the thermo-on set temperature, and the lower limit set pressure is set to be higher than the refrigerant saturation pressure at the thermo-off set temperature. The stop set pressure is set to be smaller than the refrigerant saturation pressure at the thermo-off set temperature.

  Then, when the operation start command signal is input from the operation control device 8, the control device 13 of the condensing unit 6 determines whether the suction pressure of the compressor 1 is equal to or higher than the upper limit set pressure (= start set pressure). Then, when it is determined that the pressure is equal to or higher than the upper limit set pressure, the compressor 1 starts to be driven. When the compressor 1 is being driven and the suction pressure is equal to or higher than the upper limit set pressure, the rotational speed of the compressor 1 is increased. Further, when the suction pressure is less than the upper limit set pressure and greater than or equal to the lower limit set pressure, the rotation speed of the compressor 1 is maintained. Further, when the suction pressure is less than the lower limit set pressure and greater than or equal to the stop set pressure, the rotation speed of the compressor is decreased, and when the suction pressure becomes less than the stop set pressure, the compressor 1 is stopped.

A major feature of the case in the present reference embodiment, the operation control unit 8 has an operating unit not shown (such as those configured in such switches and monitors,), the thermo-setting temperature and thermo-off set temperature by the operation unit It can be changed. That is, the operation control device 8 rewrites the thermo-on set temperature and the thermo-off set temperature stored in the internal memory and outputs them to the condensing unit 6.

  The control device 13 of the condensing unit 6 stores an operation table in the internal memory (specifically, a combination of a thermo-on set temperature and an upper limit set temperature set to be lower than the saturation pressure of the refrigerant at the salmon temperature, a thermo-off set temperature) And the lower limit set temperature set to be larger than the saturation pressure of the refrigerant at the thermo-off set temperature, and the stop set pressure set to be smaller than the saturation pressure of the refrigerant at the thermo-off set temperature and the thermo-off set temperature. Based on this calculation table, the upper limit set pressure, lower limit set pressure, and stop set pressure are automatically set according to the thermo-on set temperature and thermo-off set temperature input from the operation control device 8. It is supposed to change to.

  As a specific example, for example, as shown in FIG. 3, when the thermo-on set temperature a1 is changed to a2 (where a1> a2), the upper limit set pressure (= start set pressure) c1 (where c1 <a1) To c2 (where c1 <a2). When the thermo-off set temperature b1 is changed to b2 (where b1> b2), the lower limit set pressure d1 (where d1> b1) to d2 (where d2> b2), the stop set pressure e1 (where It automatically changes from e1 <b1) to e2 (where e2 <b2).

In this reference embodiment configured as described above, even if changes are made of thermo setting temperature and thermo-off set temperature in the operation control unit 8, the control device 13 of the condensing unit 6, cooling failure or the liquid flowback operation The set pressure can be automatically changed so that it does not occur. That is, by automatically changing the upper limit set pressure and the lower limit set pressure so as to be located between the refrigerant saturation pressure at the thermo-on set temperature and the refrigerant saturation pressure at the thermo-off set temperature, cooling failure and liquid back operation are performed. Can be prevented. Further, it is possible to easily change the thermo-on set temperature and the thermo-off set temperature according to the user's request without depending on a specialized trader.

In the first reference embodiment, the control device 13 of the condensing unit 6 has been described by taking as an example the case where the upper limit set pressure and the start set pressure are set to be the same. However, the present invention is not limited to this and is different. You may set as follows. In the first reference embodiment, the case where the start set pressure and the stop set pressure are automatically changed according to the thermo-on set temperature and the thermo-off set temperature has been described as an example, but the present invention is not limited to this. That is, for example, the stop set pressure may be fixed at a value smaller than the refrigerant saturation pressure at the minimum value of the thermo-off set temperature (changeable minimum value). For example, when the outside air temperature detected by an outside air temperature sensor (not shown) is lower than a predetermined threshold value (for example, 0 ° C.), a predetermined start set pressure ( (Fixed value) may be used. In these cases, the same effect as described above can be obtained.

Next, a second reference embodiment of the present invention will be described. Note that in this reference embodiment, the same parts as those in the first reference embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

In this preferred embodiment, the operation controller 8, as in the first referential embodiment, rewrites the thermo setting temperature and thermo-off set temperature inputted by the operation unit in the internal memory, so as to output the condensing unit 6 ing.

  The control device 13 of the condensing unit 6 stores the start set pressure and the stop set pressure in the internal memory in advance. When an operation start command signal is input from the operation control device 8, it is determined whether or not the suction pressure of the compressor 1 is equal to or higher than the start set pressure. Start driving. Further, when the suction pressure becomes less than the stop set pressure, the compressor 1 is stopped.

  In addition, the control device 13 stores in the internal memory the first calculation table (specifically, the combination of the thermo-on set temperature and the start set temperature set to be smaller than the saturation pressure of the refrigerant at the salmon temperature, and the thermo-off set temperature. And a combination of a stop set pressure set to be smaller than the saturation pressure of the refrigerant at the thermo-off set temperature) and a thermo-on setting input from the operation control device 8 based on the first calculation table. The start set pressure and the stop set pressure are automatically changed according to the temperature and the thermo-off set temperature.

  Further, the control device 13 inputs the internal temperature detected by the internal temperature sensor 10 via the operation control device 8, and automatically changes the upper limit set pressure and the lower limit set pressure so as to follow this. More specifically, the control device 13 stores a second calculation table (specifically, a combination of an internal temperature and a temperature difference setting value that varies in accordance with the second calculation table) in the internal memory. Based on the above, the temperature difference set value corresponding to the internal temperature detected by the internal temperature sensor 10 is read. Then, the target value of the evaporation temperature is calculated by subtracting the temperature difference set value from the internal temperature, the target value of the suction pressure with the target value of the evaporation temperature as the saturation temperature of the refrigerant is calculated, and the target value of the suction pressure The upper limit set pressure and the lower limit set pressure are calculated so that becomes an intermediate value between the upper limit set pressure and the lower limit set pressure.

  As a specific example, as shown in FIG. 4, for example, a target value Tb1 of the evaporation temperature is calculated by subtracting the corresponding temperature difference set value ΔT1 from the internal temperature Ta1, and the target value Tb1 of the evaporation temperature is calculated as the saturation temperature of the refrigerant. The target value f1 of the suction pressure is calculated, and the upper limit set pressure g1 and the lower limit set pressure h1 are calculated so that the target value f1 of the suction pressure becomes an intermediate value. Further, for example, a target value Tb2 of the evaporation temperature is calculated by subtracting the corresponding temperature difference set value ΔT2 (≠ ΔT1) from the internal temperature Ta2 (≠ Ta1), and the target value Tb2 of the evaporation temperature is set as the saturation temperature of the refrigerant. The target value f2 of the suction pressure is calculated, and the upper limit set pressure g2 and the lower limit set pressure h2 are calculated so that the target value f2 of the suction pressure becomes an intermediate value.

  Then, the control device 13 increases the rotational speed of the compressor 1 when the suction pressure is equal to or higher than the upper limit set pressure during driving of the compressor 1 (however, when the suction pressure is equal to or higher than the stop set pressure). . Further, when the suction pressure is less than the upper limit set pressure and is not less than the lower limit set pressure (however, when the suction pressure is not less than the stop set pressure), the rotation speed of the compressor 1 is maintained. Further, when the suction pressure is less than the lower limit set pressure (however, when the suction pressure is equal to or higher than the stop set pressure), the rotation speed of the compressor is decreased.

In this reference embodiment configured as described above, even if changes are made of thermo setting temperature and thermo-off set temperature, so that the cooling failure or the liquid flowback operation does not occur, to automatically change the set pressure it can. That is, by automatically changing the upper limit set pressure and the lower limit set pressure so as to follow the internal temperature, it is possible to prevent cooling failure and liquid back operation.

Next, an embodiment of the present invention will be described. In the present embodiment, the control device 13 of the condensing unit 6 calculates the evaporation temperature from the suction pressure detected by the suction pressure sensor 11, and the difference between the suction gas temperature detected by the suction gas temperature sensor 12 and the evaporation temperature. It calculates the degree of superheating is, to correct the temperature difference setting value as the degree of superheating approaches the preset predetermined target value. As a specific example, for example, as shown in FIG. 5, first, the corresponding temperature difference set value ΔT3 (specifically, a value based on the above calculation table stored in the internal memory) is subtracted from the internal temperature Ta3. Then, a target value Tb3 of the evaporation temperature is calculated, a target value f3 of the suction pressure with the target value Tb3 of the evaporation temperature as the saturation temperature of the refrigerant is calculated, and an upper limit is set so that the target value f3 of the suction pressure becomes an intermediate value. The set pressure g3 and the lower limit set pressure h3 are calculated. Thereafter, for example, it is determined whether or not the refrigeration cycle is stable by determining whether or not the suction pressure detected by the suction pressure sensor 11 remains in the vicinity of the target value for a predetermined time. For example, when it is determined that the refrigeration cycle is stable, the degree of superheat calculated as described above and a predetermined target value E set in advance (specifically, the liquid back operation is not performed and the operation efficiency is increased). And the temperature difference set value is corrected so that the difference becomes small when the difference is large. That is, the correction value α is subtracted from the temperature difference set value ΔT4 (specifically, the value based on the above-described calculation table stored in the internal memory) corresponding to the internal temperature Ta4 to correct to the internal temperature The target value Tb4 of the evaporation temperature is calculated by subtracting the temperature setting value ΔT4 ′ from Ta4, the target value f4 of the suction pressure with the target value Tb4 of the evaporation temperature as the saturation temperature of the refrigerant is calculated, and the target value of this suction pressure The upper limit set pressure g4 and the lower limit set pressure h4 are calculated so that f4 becomes an intermediate value. In this embodiment , the driving efficiency can be further improved.

In the second reference embodiment, the control device 13 of the condensing unit 6 will be described by taking an example in which the start set pressure and the stop set pressure are automatically changed according to the thermo-on set temperature and the thermo-off set temperature. However, it is not limited to this. That is, for example, the stop set pressure may be fixed at a value smaller than the refrigerant saturation pressure at the minimum value of the thermo-off set temperature. For example, when the outside air temperature detected by an outside air temperature sensor (not shown) is lower than a predetermined threshold value (for example, 0 ° C.), a predetermined start set pressure ( (Fixed value) may be used. In these cases, the same effect as described above can be obtained.

DESCRIPTION OF SYMBOLS 1 Compressor 2 Condenser 3 Expansion valve 4 Evaporator 5 Refrigerator 8 Operation control apparatus (operation control means)
10 Internal temperature sensor 11 Suction pressure sensor 12 Suction gas temperature sensor 13 Control device (compressor control means)

Claims (1)

A refrigeration cycle comprising a compressor, a condenser, an expansion valve, and an evaporator;
A refrigerator to which a medium to be cooled cooled by the evaporator is supplied;
An internal temperature sensor for detecting the temperature in the refrigerator;
When the internal temperature detected by the internal temperature sensor is equal to or higher than the thermo-on set temperature, the operation start of the refrigeration cycle is instructed, and the internal temperature detected by the internal temperature sensor is less than the thermo-off set temperature. Operation control means for commanding the operation stop of the refrigeration cycle when
Set temperature changing means capable of changing the thermo-on set temperature and the thermo-off set temperature;
A suction pressure sensor for detecting the suction pressure of the compressor;
When the suction pressure detected by the suction pressure sensor is equal to or higher than the upper limit set pressure, the number of revolutions of the compressor is increased, and the suction pressure detected by the suction pressure sensor is lower than the upper limit set pressure and higher than the lower limit set pressure. Refrigeration provided with compressor control means for maintaining the rotational speed of the compressor in some cases and reducing the rotational speed of the compressor when the suction pressure detected by the suction pressure sensor is less than a lower limit set pressure In the device
Set pressure changing means for automatically changing the set pressure so as to follow the inside temperature detected by the inside temperature sensor ;
An intake gas temperature sensor for detecting an intake gas temperature of the compressor;
An evaporation temperature is calculated from the suction pressure detected by the suction pressure sensor, and a superheat degree calculation means for calculating a superheat degree that is a difference between the suction gas temperature and the evaporation temperature detected by the suction gas temperature sensor,
The set pressure changing means includes
The temperature difference set value is corrected so that the superheat degree calculated by the superheat degree calculating means approaches a predetermined target value set in advance,
Subtracting the corrected temperature difference set value from the internal temperature detected by the internal temperature sensor to calculate the target value of the evaporation temperature,
Calculate the target value of the suction pressure with the target value of the evaporation temperature as the saturation temperature of the refrigerant,
The refrigeration apparatus , wherein the upper limit set pressure and the lower limit set pressure are changed so that a target value of the suction pressure becomes an intermediate value between the upper limit set pressure and the lower limit set pressure .

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