JP4245363B2 - Cooling system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a cooling device including a refrigerant circuit including a compressor capable of controlling the rotation speed.
[0002]
[Prior art]
A conventional cooling device, for example, a showcase installed in a store, includes a compressor, a gas cooler (condenser) and a throttle means (capillary tube, etc.) constituting a condensing unit, and an evaporator provided on the cooling device main body side. A refrigerant cycle (refrigerant circuit) is configured by sequentially connecting pipes in an annular shape. Then, the refrigerant gas compressed by the compressor and having a high temperature and a high pressure is discharged to the gas cooler. The refrigerant gas radiates heat in the gas cooler, and is then squeezed by the squeezing means and supplied to the evaporator. Therefore, the refrigerant evaporates, and at that time, the cooling effect is exhibited by absorbing heat from the surroundings to cool the inside of the showcase (see, for example, Patent Document 1).
[0003]
[Patent Document 1]
JP-A-11-257830
[0004]
[Problems to be solved by the invention]
Incidentally, the rotation speed of the compressor is normally controlled between the minimum rotation speed and the maximum rotation speed by the control device. That is, when the inside temperature of the showcase reaches the upper limit temperature, the control device starts (ON) the compressor. Then, the control device controls the rotation speed of the compressor within the range of the preset minimum rotation speed and maximum rotation speed as shown in FIG. 4 based on the output of various sensors for detecting the temperature of the refrigerant. . Then, the compressor is stopped (OFF) when the inside temperature of the showcase is lowered to the lower limit temperature. As a result, the interior of the showcase was kept at a predetermined temperature.
[0005]
Here, the maximum number of revolutions and the minimum number of revolutions of the compressor are set in advance as described above, and the maximum number of revolutions is set high in order to obtain a necessary cooling capacity at the time of pull-down when the power is turned on or after the defrosting operation is completed. Thus, the cooling efficiency at the time of pull-down has been improved.
[0006]
However, during normal operation other than the pull-down, the compressor is frequently turned on and off at a high maximum rotational speed, which causes a problem of increased power consumption.
[0007]
The present invention has been made to solve the conventional technical problem, and an object of the present invention is to provide a cooling device capable of reducing power consumption while maintaining the cooling capacity during pull-down. To do.
[0008]
[Means for Solving the Problems]
That is, the cooling device of the invention of claim 1 includes a control device that controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed. During steady operation, the compressor speed is controlled between the minimum speed and the maximum speed, Since the compressor speed is controlled by setting the maximum compressor speed during pull-down higher than the maximum speed during steady operation, power consumption during normal operation is reduced while maintaining cooling capacity during pull-down. Will be able to.
[0009]
In the cooling device of the second aspect of the present invention, the cooling device includes a control device that controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed, and a temperature sensor that detects the outside air temperature. While controlling the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed during steady operation, Since the maximum number of revolutions of the compressor is changed based on the outside temperature detected by the temperature sensor, for example, if the maximum number of revolutions of the compressor is increased as the outside temperature rises by the control device as in claim 3, It becomes possible to ensure the cooling capacity at the time of high load.
[0010]
Further, when the outside air temperature is low, the maximum rotational speed is lowered by the control device, so that power consumption can be suppressed. Thereby, an efficient driving | operation can be implement | achieved.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a refrigerant circuit diagram of a cooling device 110 to which the present invention is applied. The cooling device 110 includes a condensing unit 100 and a refrigeration equipment main body 105 serving as a cooling equipment main body. The cooling device 110 according to the embodiment is, for example, a showcase installed in a store. Therefore, the refrigeration apparatus main body 105 is a main body of the showcase.
[0012]
The condensing unit 100 includes a compressor 10, a gas cooler (condenser) 40, a capillary tube 58 as decompression means, and the like. The condensing unit 100 is connected to an evaporator 92 of a refrigeration apparatus main body 105 to be described later by piping. The capillary tube 58 and the evaporator 92 constitute a predetermined refrigerant circuit.
[0013]
That is, the refrigerant discharge pipe 24 of the compressor 10 is connected to the inlet of the gas cooler 40. Here, the compressor 10 of the embodiment has carbon dioxide (CO ₂ ) As an internal intermediate pressure multi-stage (two-stage) compression rotary compressor. The compressor 10 is an electric element as a driving element provided in a hermetic container (not shown) and a first driven by the electric element. It consists of a rotary compression element (first stage) and a second rotary compression element (second stage).
[0014]
In the figure, reference numeral 20 denotes a refrigerant introduction pipe for temporarily discharging the refrigerant compressed by the first rotary compression element of the compressor 10 and discharged into the hermetic container to the outside and introducing it into the second rotary compression element. One end of the refrigerant introduction pipe 20 communicates with a cylinder of a second rotary compression element (not shown). The refrigerant introduction pipe 20 passes through an intermediate cooling circuit 35 provided in a gas cooler 40, which will be described later, and the other end communicates with the sealed container.
[0015]
In the figure, reference numeral 22 denotes a refrigerant introduction pipe for introducing refrigerant into a cylinder of a first rotary compression element (not shown) of the compressor 10, and one end of the refrigerant introduction pipe 22 is connected to a cylinder of the first rotary compression element (not shown). Communicate. The refrigerant introduction pipe 22 is connected to one end of the strainer 56. The strainer 56 is for securing and filtering foreign matters such as dust and cutting waste mixed in the refrigerant gas circulating in the refrigerant circuit, and an opening formed on the other end side of the strainer 56 and the opening. To the one end side of the strainer 56 is provided with a filter (not shown) having a substantially conical shape that becomes narrower. The opening of the filter is mounted in close contact with the refrigerant pipe 28 connected to the other end of the strainer 56.
[0016]
The refrigerant discharge pipe 24 is a refrigerant pipe for causing the gas cooler 40 to discharge the refrigerant compressed by the second rotary compression element.
[0017]
The gas cooler 40 described above includes a plurality of fins (not shown) and a refrigerant pipe inserted through a hole provided at the center of the fin. The gas cooler 40 is provided with an outside air temperature sensor 74 as a temperature sensor for detecting the outside air temperature. The outside air temperature sensor 74 is connected to a microcomputer 80, which will be described later, as a control device of the condensing unit 100. Has been.
[0018]
The refrigerant pipe 26 exiting the gas cooler 40 passes through the internal heat exchanger 50 through the strainer 54 and the electromagnetic valve 45 similar to those described above. This internal heat exchanger 50 is for exchanging heat between the high-pressure side refrigerant from the second rotary compression element coming out of the gas cooler 40 and the low-pressure side refrigerant coming out of the evaporator 92 provided in the refrigeration equipment main body 105. Is. The electromagnetic valve 45 is connected to the microcomputer 80. The microcomputer 80 controls the electromagnetic valve 45 to be opened when the compressor 10 is started and to be closed when the operation of the compressor 10 is stopped.
[0019]
The high-pressure side refrigerant pipe 26 that has passed through the internal heat exchanger 50 reaches a capillary tube 58 that is a throttle means. The refrigerant pipe 26 exiting the capillary tube 58 is connected to the inlet of the valve device 60 (the high pressure side valve device). Further, a sedge lock joint 55 as a connecting means is attached to one end of the refrigerant pipe 94 of the refrigeration equipment main body 105.
[0020]
The sedge lock joint 55 is for detachably connecting the valve device 60 and one end of the refrigerant pipe 94 extending from the refrigeration equipment main body 105, and is made of a metal attached to one end of the refrigerant pipe 94. It is comprised from the nut member and the metal ring members included in this nut member. The inner wall of the nut member is formed with a screw groove that is screwed with the screw groove at the outlet of the valve device 60, and has a through hole through which the refrigerant pipe 94 is inserted.
[0021]
And when attaching this sedge lock joint 55 to the exit of the valve apparatus 60, after inserting a nut member from the edge part of the refrigerant | coolant piping 94, a ring member is inserted. Then, in a state where the ring member is included in the nut member, the screw groove of the outlet of the valve device 60 and the screw groove of the nut member are screwed together. By screwing, the inner ring member of the nut member comes into close contact with the inner surface of the nut member and the refrigerant pipe 94, whereby the valve device 60 and the refrigerant pipe 94 are connected in a sealed state. In this state, even if the pressure in the pipe rises to a high pressure, the leakage of the refrigerant from the connecting portion can be avoided or eliminated as much as possible, and it can be easily removed by releasing the screwing. .
[0022]
On the other hand, the refrigerant pipe 28 connected to the other end of the strainer 56 is connected to the outlet of the valve device 66 (low pressure side valve device) through the internal heat exchanger 50. Further, a sedge lock joint 55 as a connecting means similar to the above is attached to the other end of the refrigerant pipe 94 of the refrigeration equipment main body 105. The other end of the refrigerant pipe 94 extending from the refrigeration apparatus main body 105 is detachably connected to the inlet of the valve device 66 by the sedge lock joint 55 as described above.
[0023]
The refrigerant discharge pipe 24 is provided with a discharge sensor 70 for detecting the temperature of the refrigerant gas discharged from the compressor 10 and a high-pressure switch 72 for detecting the pressure of the refrigerant gas. It is connected.
[0024]
The refrigerant pipe 26 between the capillary tube 58 and the valve device 60 is provided with a refrigerant temperature sensor 76 for detecting the temperature of the refrigerant discharged from the capillary tube 58. This is also provided in the microcomputer 80. It is connected.
[0025]
Reference numeral 40F denotes a fan for ventilating and cooling the gas cooler 40, and reference numeral 92F denotes a cooling air exchanged with an evaporator 92 provided in a duct (not shown) of the refrigeration equipment main body 105. A fan to circulate. Reference numeral 65 denotes a current sensor for detecting the energization current of the aforementioned electric element of the compressor 10 and controlling the operation. The fan 40F and the current sensor 65 are connected to the microcomputer 80 of the condensing unit 100, and the fan 92F is connected to a control device 90 (described later) of the refrigeration equipment body 105.
[0026]
Here, the microcomputer 80 is a control device that controls the condensing unit 100, and the discharge sensor 70, the high pressure switch 72, the outside air temperature sensor 74, the refrigerant temperature sensor 76, the current sensor 65, and the like are input to the microcomputer 80. A signal from a control device 90 as a control unit of the refrigeration equipment main body 105 is connected. Based on these outputs, the solenoid valve 45 and the fan 40F connected to the outputs are controlled. Further, the microcomputer 80 controls the rotational speed of the compressor 10 between a preset minimum rotational speed and a maximum rotational speed based on each output described above.
[0027]
That is, when the temperature of the refrigerant gas detected from the discharge sensor 70, the refrigerant temperature sensor 76, etc. is high within the range of the set minimum rotation speed and maximum rotation speed, the rotation speed of the compressor is increased to increase the refrigerant flow. When the temperature is low, the rotational speed is controlled to be low.
[0028]
Thus, by controlling the rotation speed of the compressor within the range between the set minimum rotation speed and the maximum rotation speed, the rotation speed increases excessively and the pressure on the high pressure side compressed by the compressor 10 abnormally increases. Inconvenience can be prevented. In particular, when carbon dioxide is used as the refrigerant, the high pressure side of the carbon dioxide refrigerant has a supercritical pressure. Therefore, regardless of the outside air temperature, the pressure increases as the rotation speed of the compressor 10 increases. There is a risk that the pressure will exceed the design pressure (pressure resistance) of the equipment of the cooling device 110. However, by providing an upper limit for the maximum number of rotations, it is possible to control the pressure on the high pressure side so as not to exceed the design pressure, and the durability of the compressor 10 can be improved. On the other hand, since the time for returning to the steady operation can be shortened by increasing the maximum number of rotations set at the time of pull-down, the cooling capacity of the cooling device 110 can be improved.
[0029]
Further, the maximum rotational speed has different values at the time of pull-down such as startup after power-on or after defrosting operation and at the time of steady operation other than at the time of pull-down. That is, the microcomputer 80 controls the rotational speed of the compressor 10 by setting the maximum rotational speed at the time of pull-down higher than the maximum rotational speed at the time of steady operation. For this reason, at the time of pull-down, the temperature inside the refrigerator apparatus main body 105 can be made to reach an appropriate temperature at an early stage.
[0030]
Meanwhile, during normal operation (During steady operation) Since it is not necessary to cool down rapidly as in the case of pull-down, an increase in power consumption can be suppressed by lowering the maximum rotational speed. This makes it possible to reduce power consumption during normal operation while maintaining cooling efficiency during pull-down.
[0031]
As the refrigerant of the cooling device 110, the above-mentioned carbon dioxide (CO) which is environmentally friendly and is a natural refrigerant in consideration of flammability and toxicity. ₂ As the lubricating oil, existing oils such as mineral oil (mineral oil), alkylbenzene oil, ether oil, ester oil, PAG (polyalkyl glycol) are used.
[0032]
The control device 90 of the refrigerator main body 105 stops the above-described internal temperature sensor for detecting the internal temperature of the cold refrigerator main body 105, the temperature adjustment dial for adjusting the internal temperature, and other compressors 10 are stopped. A function is provided for this purpose. Based on these outputs, the control device 90 controls the fan 92F and sends an ON / OFF signal of the compressor 10 to the microcomputer 80 of the condensing unit 100. That is, the control device 90 sends an ON signal to the microcomputer 80 when the internal temperature of the refrigeration equipment body 105 reaches + 7 ° C., which is the upper limit temperature, and OFF when it reaches + 3 ° C., which is the lower limit temperature.
[0033]
The refrigeration equipment body 105 includes an evaporator 92 and the refrigerant pipe 94 that passes through the evaporator 92. The refrigerant pipe 94 passes through the evaporator 92 in a meandering manner, and a fin for heat exchange is attached to the meandering portion to constitute the evaporator 92. Both ends of the refrigerant pipe 94 are detachably connected by the valve devices 60 and 66 of the condensing unit 100 and the sedge lock joints 55 and 55 by the connection method described above.
[0034]
Next, the operation of the cooling device 110 will be described. The valve devices 60 and 66 are fully opened. When a start switch (not shown) provided in the refrigeration equipment body 105 is turned on, or when the power socket of the refrigeration equipment body 105 is connected to an outlet, the microcomputer 80 opens the electromagnetic valve 45 and the compressor 10 is not shown. Start the motorized element. At this time, the microcomputer 80 operates the compressor 10 with the maximum rotational speed set high. The microcomputer 80 counts that pull-down has been performed.
[0035]
Then, the refrigerant is sucked into the first rotary compression element of the compressor 10 and compressed, and the refrigerant gas discharged into the sealed container enters the refrigerant introduction pipe 20, exits the compressor 10, and flows into the intermediate cooling circuit 35. The intermediate cooling circuit 35 dissipates heat by an air cooling method while passing through the gas cooler 40.
[0036]
Thereby, since the refrigerant | coolant suck | inhaled by the 2nd rotation compression element can be cooled, the temperature rise in an airtight container can be suppressed and the compression efficiency in a 2nd rotation compression element can also be improved. Further, it is possible to suppress an increase in the temperature of the refrigerant that is compressed and discharged by the second rotary compression element.
[0037]
Then, the cooled intermediate-pressure refrigerant gas is sucked into the second rotary compression element of the compressor 10 and compressed in the second stage to become high-pressure and high-temperature refrigerant gas, which is discharged to the outside through the refrigerant discharge pipe 24. . The refrigerant gas discharged from the refrigerant discharge pipe 24 flows into the gas cooler 40, where it dissipates heat by an air cooling system, and then passes through the internal heat exchanger 50 through the strainer 54 and the electromagnetic valve 45. The refrigerant is further cooled by taking heat away from the low-pressure side refrigerant.
[0038]
Due to the presence of the internal heat exchanger 50, the refrigerant that exits the gas cooler 40 and passes through the internal heat exchanger 50 is deprived of heat by the low-pressure side refrigerant, and accordingly, the degree of supercooling of the refrigerant increases. . Therefore, the cooling capacity in the evaporator 92 is improved.
[0039]
The refrigerant gas on the high pressure side cooled by the internal heat exchanger 50 reaches the capillary tube 58. The pressure of the refrigerant decreases in the capillary tube 58, and then flows into the evaporator 92 from the refrigerant pipe 94 of the refrigeration apparatus main body 105 through the valve device 60 and the sedge lock joint 55. Therefore, the refrigerant evaporates and absorbs heat from the surrounding air, thereby exerting a cooling action to cool the inside of the refrigerator apparatus main body 105.
[0040]
Thereafter, the refrigerant flows out of the evaporator 92 and reaches the internal heat exchanger 50 from the refrigerant pipe 94 through the sedge lock joint 55 and the valve device 66 of the condensing unit 100. Therefore, heat is taken from the above-described high-pressure side refrigerant and is subjected to a heating action. Here, the refrigerant 92 evaporates to a low temperature, and the refrigerant exiting the evaporator 92 is not in a completely gas state but in a liquid mixture. However, the refrigerant passes through the internal heat exchanger 50 and is on the high pressure side. The refrigerant is heated by exchanging heat with the refrigerant. At this point, the degree of superheat of the refrigerant is ensured and is completely gas.
[0041]
Thereby, since the refrigerant discharged from the evaporator 92 can be reliably gasified, it is possible to reliably prevent liquid back into which the liquid refrigerant is sucked into the compressor 10 without providing an accumulator or the like on the low pressure side. The disadvantage that the compressor 10 is damaged by liquid compression can be avoided. Therefore, the reliability of the cooling device 110 can be improved.
[0042]
The refrigerant heated by the internal heat exchanger 50 repeats a cycle of being sucked into the first rotary compression element of the compressor 10 from the refrigerant introduction pipe 22 via the strainer 56.
[0043]
Here, when the inside of the refrigerator main body 105 is sufficiently cooled and the internal temperature is lowered to the set lower limit temperature (+ 3 ° C.), the control device 90 of the refrigerator main body 105 sends an OFF signal of the compressor 10 to the microcomputer. Send to 80. Thereby, the microcomputer 80 stops the operation of the compressor 10.
[0044]
Thereafter, when the internal temperature of the refrigerator main body 105 reaches the set upper limit temperature (+ 7 ° C.), the control device 90 of the refrigerator main body 105 sends an ON signal of the compressor 10 to the microcomputer 80. Thereby, the microcomputer 80 restarts the operation of the compressor 10. At this time, completion of the pull-down is counted in the microcomputer 80, and it is determined that the restart is for normal operation. For this reason, the maximum number of revolutions is controlled to be low as shown in FIG. Thereafter, when the compressor is turned on / off based on the internal temperature sensor of the refrigeration equipment main body 105, the microcomputer 80 controls the maximum rotational speed of the compressor 10 to be low.
[0045]
On the other hand, if the operation is performed for a long time, frost is generated in the evaporator 92. When frost formation occurs in the evaporator 92, it becomes difficult for the refrigerant passing through the evaporator 92 to exchange heat with the surrounding air, and the inside of the refrigerator apparatus body 105 is not sufficiently cooled. For this reason, when a predetermined time elapses after the power is turned on, the control device 90 sends an OFF signal of the compressor 10 to the microcomputer 80 to execute defrosting of the evaporator 92. In this case, the microcomputer 80 clears the pull-down count when the power is turned on. Thereby, at the next start-up, the microcomputer 80 determines that the operation is performed at the time of pull-down, and the maximum rotational speed of the compressor 10 is controlled to be high. Similarly, since the count is cleared even when the power is stopped, the maximum rotation speed is controlled to be high at the next start-up, and the pull-down count is stored after the second time, so the maximum rotation speed is low. Be controlled.
[0046]
As described above, the microcomputer 80 has the maximum rotation speed of the compressor 10 different between the pull-down time and the normal operation, and at the time of pull-down, the maximum rotation speed is controlled to be high so that early cooling can be realized. Thus, during normal operation, the maximum rotational speed is controlled to be low, so that power consumption can be reduced.
[0047]
As a result, the power consumption can be reduced while maintaining the cooling efficiency during pull-down.
[0048]
Next, another embodiment of the present invention will be described in detail with reference to FIG. In addition, what attached | subjected the code | symbol similar to the said Example shall show | play the same or similar effect. Here, the microcomputer 80 is based on the outside air temperature detected by the outside air temperature sensor 74 attached to the gas cooler 40 during normal operation. (During steady operation) The maximum rotation speed of the compressor 10 is changed.
[0049]
That is, as shown in FIG. 3, the maximum rotation speed A in steady operation is determined in advance as a reference rotation speed Z, a reference outside air temperature b, and a slope a, and A = Z + (outside air temperature−b) × By substituting the outside air temperature detected by the outside air temperature sensor 74 into the equation a, the maximum rotational speed A during the steady operation of the microcomputer 80 is calculated. Then, the number of rotations of the compressor 10 is controlled with the numerical value calculated by the equation as the maximum number of rotations A. The maximum rotation speed B at the time of pull-down is set to a preset value, for example, 80 Hz, as in the above-described embodiment, and the minimum rotation speed is also set to a preset value, for example, 30 Hz.
[0050]
As a result, during normal operation, when the outside air temperature is high, the maximum rotational speed A calculated by the above equation also increases, so that the cooling efficiency can be improved. Further, when the outside air temperature is low, the maximum rotational speed A of the compressor 10 becomes low, so that power consumption can be reduced.
[0051]
When the maximum rotational speed A of the compressor 10 during normal operation calculated by the above formula exceeds the maximum rotational speed B at the time of pull-down, the maximum at the time of pull-down regardless of the value calculated by the above formula. It is operated at the rotation speed B. As a result, it is possible to prevent the inconvenience that the maximum rotational speed increases too much and the power consumption increases. In this embodiment, when the maximum rotational speed A of the compressor 10 during normal operation calculated by the above formula exceeds the maximum rotational speed B at the time of pull-down, regardless of the value calculated by the above formula. It is assumed that the engine is operated at the maximum rotation speed B at the time of pull-down. However, the present invention is not limited to this. When A exceeds the upper limit value C of the set maximum rotational speed, it may be operated at the set upper limit value C regardless of the value calculated by the equation.
[0052]
Next, the control method will be described. When a start switch (not shown) provided in the refrigeration equipment body 105 is turned on, or when the power socket of the refrigeration equipment body 105 is connected to an outlet, the microcomputer 80 opens the electromagnetic valve 45 and the compressor 10 is not shown. Start the motorized element. At this time, the microcomputer 80 operates the compressor 10 with the maximum rotational speed set high. The microcomputer 80 counts that pull-down has been performed.
[0053]
Then, the refrigerant is sucked into the first rotary compression element of the compressor 10 and compressed, and the refrigerant gas discharged into the sealed container enters the refrigerant introduction pipe 20, exits the compressor 10, and flows into the intermediate cooling circuit 35. The intermediate cooling circuit 35 dissipates heat by an air cooling method while passing through the gas cooler 40. Thereby, the refrigerant sucked into the second rotary compression element can be cooled.
[0054]
Then, the cooled intermediate-pressure refrigerant gas is sucked into the second rotary compression element of the compressor 10 and compressed in the second stage to become high-pressure and high-temperature refrigerant gas, which is discharged to the outside through the refrigerant discharge pipe 24. . The refrigerant gas discharged from the refrigerant discharge pipe 24 flows into the gas cooler 40, where it dissipates heat by an air cooling system, and then passes through the internal heat exchanger 50 through the strainer 54 and the electromagnetic valve 45. The refrigerant is further cooled by taking heat away from the low-pressure side refrigerant.
[0055]
The refrigerant gas on the high pressure side cooled by the internal heat exchanger 50 reaches the capillary tube 58. The pressure of the refrigerant decreases in the capillary tube 58, and then flows into the evaporator 92 from the refrigerant pipe 94 of the refrigeration apparatus main body 105 through the valve device 60 and the sedge lock joint 55. Therefore, the refrigerant evaporates and absorbs heat from the surrounding air, thereby exerting a cooling action to cool the inside of the refrigerator apparatus main body 105.
[0056]
Thereafter, the refrigerant flows out of the evaporator 92 and reaches the internal heat exchanger 50 from the refrigerant pipe 94 through the sedge lock joint 55 and the valve device 66 of the condensing unit 100. Therefore, heat is taken from the above-described high-pressure side refrigerant and is subjected to a heating action. Here, the refrigerant 92 evaporates to a low temperature, and the refrigerant exiting the evaporator 92 is not in a completely gas state but in a liquid mixture. However, the refrigerant passes through the internal heat exchanger 50 and is on the high pressure side. The refrigerant is heated by exchanging heat with the refrigerant. At this point, the degree of superheat of the refrigerant is ensured and is completely gas.
[0057]
The refrigerant heated by the internal heat exchanger 50 repeats a cycle of being sucked into the first rotary compression element of the compressor 10 from the refrigerant introduction pipe 22 via the strainer 56.
[0058]
Here, when the inside of the refrigerator apparatus body 105 is sufficiently cooled and the inside temperature is lowered to the set lower limit temperature, the control device 90 sends the output from the inside temperature sensor to the microcomputer 80 as an OFF signal of the compressor 10. Send to. Thereby, the microcomputer 80 stops the operation of the compressor 10.
[0059]
Thereafter, when the internal temperature of the refrigerator main body 105 reaches the set upper limit temperature, the controller 90 changes the output from the internal temperature sensor into an ON signal of the compressor 10 and sends it to the microcomputer 80. Thereby, the microcomputer 80 restarts the operation of the compressor 10. At this time, the completion of the pull-down is counted in the microcomputer 80, and therefore it is determined that the restart is a normal operation. Thus, the maximum rotational speed A calculated by the above formula based on the outside air temperature detected by the outside air temperature sensor 74 is controlled. Thereafter, when the compressor is turned on / off based on the internal temperature sensor, the microcomputer 80 controls the maximum rotational speed A of the compressor 10 by the above formula based on the outside air temperature.
[0060]
On the other hand, if the operation is performed for a long time, frost is generated in the evaporator 92. When frost formation occurs in the evaporator 92, it becomes difficult for the refrigerant passing through the evaporator 92 to exchange heat with the surrounding air, and the inside of the refrigerator apparatus body 105 is not sufficiently cooled. For this reason, the control device 90 sends a 10 OFF signal to the microcomputer 80 to perform defrosting of the evaporator 92 when a predetermined time elapses after the power is turned on. In this case, the microcomputer 80 clears the pull-down count when the power is turned on. Thereby, at the next start-up, the microcomputer 80 determines that the operation is performed at the time of pull-down, and the maximum rotational speed of the compressor 10 is controlled to be high. Similarly, since the count is cleared even when the power is stopped, the maximum rotation speed is controlled to be high at the next start-up, and the pull-down count is stored after the second time. It is controlled at the maximum rotational speed A calculated by the equation.
[0061]
As a result, the maximum rotation speed A is determined based on the outside air temperature during normal operation while maintaining the cooling capacity at the time of pull-down, so that the power consumption can be reduced while ensuring the cooling capacity at the time of high load. It becomes like this. Therefore, more efficient operation can be performed.
[0062]
【The invention's effect】
As detailed above, according to the invention of claim 1, A control device that controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed is provided. The control apparatus controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed during steady operation, Since the compressor speed is controlled by setting the maximum compressor speed during pull-down higher than the maximum speed during steady operation, power consumption during normal operation is reduced while maintaining cooling capacity during pull-down. Will be able to.
[0063]
According to the invention of claim 2, the controller includes a control device that controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed, and a temperature sensor that detects the outside air temperature. While controlling the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed during steady operation, Since the maximum number of revolutions of the compressor is changed based on the outside temperature detected by the temperature sensor, for example, if the maximum number of revolutions of the compressor is increased as the outside temperature rises by the control device as in claim 3, It becomes possible to ensure the cooling capacity at the time of high load.
[0064]
Further, when the outside air temperature is low, the maximum rotational speed is lowered by the control device, so that power consumption can be reduced. Thereby, an efficient driving | operation can be implement | achieved.
[Brief description of the drawings]
FIG. 1 is a refrigerant circuit diagram of a cooling device of the present invention.
FIG. 2 is a diagram illustrating compressor speed control of an embodiment.
FIG. 3 is a diagram illustrating rotation speed control based on an outside air temperature of a compressor according to another embodiment.
FIG. 4 is a diagram illustrating a conventional rotation speed control of a compressor.
[Explanation of symbols]
10 Compressor
20, 22 Refrigerant introduction pipe
24 Refrigerant discharge pipe
26, 28 Refrigerant piping
35 Intermediate cooling circuit
40 Gas cooler
45 Solenoid valve
50 Internal heat exchanger
54, 56 Strainer
55 Sedge Lock Fitting
58 Capillary tube
60, 66 Valve device
70 Discharge sensor
72 High pressure switch
74 Outside temperature sensor
76 Refrigerant temperature sensor
80 Microcomputer
90 Control device
92 Evaporator
94 Refrigerant piping
100 Condensing unit
105 Refrigeration equipment
110 Cooling device

Claims (3)

In a cooling device including a refrigerant circuit configured by connecting a compressor , a gas cooler, a decompression unit, and an evaporator that can control the number of revolutions,
A control device for controlling the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed;
The control device controls the rotational speed of the compressor between said minimum speed and maximum speed during normal operation, the maximum rotational speed of the compressor at the time of pull-down, than the maximum speed during the steady operation A cooling device characterized by controlling the rotational speed of the compressor by setting it high. In a cooling device including a refrigerant circuit configured by connecting a compressor , a gas cooler, a decompression unit, and an evaporator that can control the number of revolutions,
A control device for controlling the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed, and a temperature sensor for detecting the outside air temperature,
The control device controls the rotation speed of the compressor between the minimum rotation speed and the maximum rotation speed during steady operation , and changes the maximum rotation speed of the compressor based on an outside temperature detected by the temperature sensor. A cooling device characterized by.   The cooling device according to claim 2, wherein the control device increases the maximum rotation speed of the compressor as the outside air temperature increases.

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