JP4682414B2 - Storage - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inform a user of consumed electric power, the amount of the consumed electric power or the cost of the electric power of a container section in view of problems with prior art that although energy saving of a container chamber itself is promoted in response to a requirement of recent energy saving, there are desired ones capable of display of consumed electric power and the amount of consumed electric power. SOLUTION: An input current is detected by electric current detection means 1, and electric power of a container chamber is calculated with electric power calculation means 2, and further the amount of electric power is accumulated in electric power amount calculation means 3, whereby electric power or the amount of electric power is displayed on display means 7.

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a display device for a storage for storing food or the like.
[0002]
[Prior art]
Conventionally, there is a display on a storage such as a refrigerator that informs the internal temperature or set temperature.
[0003]
Hereinafter, a conventional refrigerator will be described with reference to FIG.
[0004]
In FIG. 10, reference numeral 101 denotes a refrigerator main body, with a partition wall 102 having a freezer compartment 103 at the top and a refrigerator compartment 104 at the bottom. Reference numeral 105 denotes a refrigeration cycle cooler, and 106 denotes a fan for forcibly ventilating the cold air cooled by the cooler 105 through the freezing chamber 103 and the refrigeration chamber 104, and is configured to operate in synchronization with the compressor 107 of the normal refrigeration cycle. Has been. Reference numeral 108 denotes a temperature sensor such as a thermistor provided in the freezer compartment 103, and 109 denotes display means provided on the surface of the door 110.
[0005]
Reference numeral 111 denotes temperature detection means for detecting the temperature of the temperature sensor 108. A temperature determination unit 112 adjusts the internal temperature based on the internal temperature detected by the temperature detection unit 111, determines whether the compressor 107 and the fan 106 are operated or stopped, and outputs the determined values to the compressor control unit 113.
[0006]
The compressor control unit 113 operates and stops the compressor 107 and the fan 106 according to the determination of the temperature determination unit 112.
[0007]
The operation of the refrigerator control apparatus configured as described above will be described below with reference to the flowchart of FIG.
[0008]
FIG. 11 is a schematic flowchart showing the entire control program stored in a microcomputer (hereinafter referred to as a microcomputer). First, after turning on the power, in step 100, the temperature detection means 111 detects the temperature of the temperature sensor 108, and in step 101, the temperature determination means 112 determines whether the internal temperature of the freezer compartment 103 is higher than the set value. If higher, the operation of the compressor 107 and the fan 106 is output to the compressor control means 113 in step 102, and the compressor control means 113 operates the compressor 107 and the fan 106.
[0009]
If the internal temperature is lower than the set value, the stop of the compressor 107 and the fan 106 is output to the compressor control means 113 in step 103, and the compressor control means 113 stops the compressor 107 and the fan 106.
[0010]
In step 104, the temperature detected by the temperature detecting means 111 is output to the display means 109. In step 105, the display means 109 displays the internal temperature.
[0011]
Then, returning to step 100, the same operation is repeated thereafter to perform a normal cooling action, and the temperature of the refrigerator is displayed.
[0012]
Thus, the internal temperature is displayed and the user is informed that the internal space is being cooled, thereby giving a sense of security.
[0013]
[Problems to be solved by the invention]
However, the energy saving of the storage itself has been promoted in response to the recent demand for energy saving, but it is desired to be able to display the power consumption and the amount of power consumption. In such a configuration, the temperature inside the storage is informed to the user. However, there is a problem that it is impossible to know the power consumption and the power consumption.
[0014]
An object of this invention is to notify a user of the power consumption of a storage, the amount of power consumption, or a power bill.
[0015]
[Means for Solving the Problems]
In order to solve this problem, the invention according to claim 1 of the present invention is provided. In a storage room that stores food and stores it in a refrigerator, A DC compressor equipped with a DC motor and an inverter controller that drives the DC compressor and outputs a driving duty of the DC compressor Stepped Temperature determining means for determining operation and stop of the DC compressor, and outputting operation and operation speed and stop signal to the inverter control means; With power calculation means A control means for outputting the power calculated by the power calculation means to the display means, and a display means for displaying the power by the output of the control means. The power calculation means calculates power consumption from the duty value for operating the DC compressor from the inverter control means and the operation rotational speed from the temperature determination means. Therefore, it is possible to calculate electric power without having to detect current, and to display the power of the storage and inform the user of the current power consumption.
[0016]
Claim 2 In the invention described in the above, the power consumption is calculated by the power amount calculation means from the power calculated by the power calculation means, the power amount is output to the display means by the control means, and the power amount is displayed by the display means. The power amount of the storage is displayed and the user is informed of the power consumption amount for one day or one month.
[0017]
Claim 3 In the invention described in, since the electric power is corrected by the outside air temperature detecting means and the control means by the outside air temperature detected by the outside air temperature detecting means, the power consumption can be corrected by the outside air temperature, and the accuracy of the electric energy can be improved. It has the action.
[0018]
Claim 4 The power amount storage means stores the power amount, the power amount comparison means compares the power amount stored in the power amount storage means with the power amount calculated by the power amount calculation means, and the control means Since the comparison result is output to the display means and the comparison result is displayed on the display means, the increase / decrease in the current power amount relative to the previous day or the increase / decrease in the current energy amount relative to the previous month can be displayed. It has the effect of informing changes.
[0019]
Claim 5 In the invention described in, the power cost is calculated from the power amount storage means storing the power cost per unit and the power amount calculated by the power amount calculation means, and the calculation result is output to the display means. It has the action.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0021]
In addition, the thing of the same structure as a prior art gives the same code | symbol, and the detailed description is abbreviate | omitted.
[0022]
( Reference example 1)
FIG. 1 illustrates the present invention. Reference example FIG. 2 is a block diagram of the display device in FIG. Reference example 2 is a flowchart for explaining the operation of the display device in FIG.
[0023]
In FIG. 1, reference numeral 1 denotes current detection means for detecting the input current of the compressor, and 2 denotes power calculation means for calculating power consumption from the current detected by the current detection means 1. The power consumption calculation means 3 and the control means 4 Output to.
[0024]
The power amount calculation means 3 integrates the power from the power calculation means for 24 hours, for example, calculates the daily power consumption, and outputs the power consumption to the control means 4.
[0025]
5 is a switching means for inputting a power value from the power calculating means 2, a power amount value from the power amount calculating means 3, or a signal indicating which content is to be displayed from the temperature detecting means 111 to the control means 4. Can be switched by a person.
[0026]
The control unit 4 outputs to the communication unit 7 either the power value from the power calculation unit 2, the power amount value from the power amount calculation unit 3, or the internal temperature from the temperature detection unit based on the signal from the switching unit 5. The communication unit 6 transmits the signal to the display unit 7.
[0027]
Display means 7 Displays the contents of the communication means.
[0028]
The operation of the refrigerator display device configured as described above will be described with reference to the flowchart of FIG.
[0029]
First, after turning on the power, step 1 detects the temperature of the temperature sensor 108 with the temperature detection means 111, and step 2 determines whether the temperature inside the freezer compartment 103 is higher than the set value with the temperature determination means 112. If it is higher, the operation of the compressor 107 and the fan 106 is output to the compressor control means 113 in step 3, and the compressor control means 113 operates the compressor 107 and the fan 106.
[0030]
If the internal temperature is lower than the set value, the stop of the compressor 107 and the fan 106 is output to the compressor control means 113 in step 4, and the compressor control means 113 stops the compressor 107 and the fan 106.
[0031]
Next, the step 5 input current is input by the current detection means 1, and the step 6 power consumption is calculated by the power calculation means 3.
[0032]
Next, step 7 the electric energy calculation means 3 integrates the electric energy. For example, the amount of power consumption is obtained by integrating the amount of power consumed for 24 hours as the amount of power consumed per day.
[0033]
Next, it is determined whether or not the power consumption calculating means 3 in step 8 has integrated the power consumption for 24 hours. If the power consumption is integrated for 24 hours, the power consumption for one day is obtained in step 9 and the power consumption for 24 hours is newly added from the next time. Starts accumulating. The daily power consumption determined in step 9 is valid until the newly integrated power consumption is determined.
[0034]
If the 24-hour integration is not performed in step 8, the daily power consumption is not determined and the process proceeds to step 10.
[0035]
In step 10, the control means 4 determines whether the switching means 5 is displaying the temperature. If the temperature is displayed, in step 11, the internal temperature is input from the temperature detection means 111 and the content is output to the communication means 6. To do.
[0036]
If the temperature is not displayed in step 10, it is determined whether the power is displayed or the amount of power is displayed in step 12. If the power is displayed, the power is input from the power calculation means 2 in step 13 and the content is displayed. If it is output to the communication means 6 and the power amount is displayed, the power amount is input from the power amount calculation means 3 in step 14 and the content is output to the communication means 6.
[0037]
In step 15, the communication unit 6 outputs the content from the control unit 4 to the display unit 7, and in step 17 the display unit 7 displays the transmitted content.
[0038]
Thus, since the power is displayed, the current power consumption can be notified to the user.
[0039]
Further, the power consumption amount can be calculated from the power and displayed to display the power amount of the storage, and the user can be informed of the power consumption amount for one day or one month.
[0040]
Further, since the display contents are transmitted by the communication means 6, the power and the power amount can be displayed even at a remote place.
[0041]
The switching means 5 can select display contents that the user wants to know.
[0042]
(Embodiment 1 )
FIG. 3 shows an embodiment of the present invention. 1 FIG. 4 is a block diagram of a display device according to the present invention. 1 It is a flowchart for demonstrating operation | movement of the display apparatus in FIG. In FIG. 3, the same components as those of the conventional technology are denoted by the same reference numerals, and detailed description thereof is omitted.
[0043]
10 is a DC compressor equipped with a DC motor, 11 is a temperature determination means for adjusting the internal temperature based on the internal temperature detected by the temperature detection means 111, and the rotational speed command of the DC compressor 10 is an inverter control means 12. Output to. This is, for example, 0 when the internal temperature is −20 ° C. or lower, 2400 rps when the internal temperature is −20 to −18 ° C., 3600 rps when the internal temperature is −18 to −16 ° C., and the internal temperature When the temperature is −16 ° C. or higher, a rotational speed command of 4800 rps is output to the inverter control means 12. The inverter control means 12 has the configuration shown in FIG.
[0044]
In FIG. 5, 12-1 is an AC power source, 12-2 is a rectifier circuit that converts AC power into DC, 12-3 is a capacitor that smoothes DC, 12-4 is a power circuit that drives the DC compressor 20, and 12-5. Is a drive circuit, and outputs a waveform for operating the DC compressor 10 to the power circuit 12-4 in response to a rotational speed command from the temperature determination means 111.
[0045]
A fan drive circuit 12-6 operates the fan 106 if the rotational speed command from the temperature determination means 111 is not 0, and stops the fan 106 if it is 0.
[0046]
As shown in FIG. 6, the waveforms of the drive circuit 12-5 are drive signals A, / A, B, for driving the DC motor to the power circuit in accordance with the position signals X, Y, Z detected for the position of the DC motor of the DC compressor 10. / B, C, and / C are output, and a voltage control signal is output in order to keep the rotation speed constant. When this voltage control signal is ON, the voltage VDC at both ends of the smoothing capacitor 12-3 is supplied to the DC compressor 10, and when it is OFF, the voltage VDC at both ends of the smoothing capacitor 12-3 is not supplied to the DC compressor 10.
[0047]
As shown in FIG. 6 (a), when the duty, which is the ratio of the ON time to the total time (ON time + OFF time), is large, the ON time becomes long, and the voltage VDC at both ends of the smoothing capacitor 12-3 becomes DC compressor. Since the time supplied to 10 becomes longer, the voltage supply becomes larger and the DC compressor 10 rotates at a high speed. As shown in FIG. 6B, when the duty is small, the ON time is shortened, and the smoothing capacitor 12 Since the time during which the VDC having the voltage at both ends of −3 is supplied to the DC compressor 10 is shortened, the voltage supply to the DC compressor 10 is reduced and the DC compressor 10 rotates at a low speed.
[0048]
Therefore, when the interior is at a high temperature or the like, the load on the DC motor increases, and the rotational speed decreases even with the same duty. In order to keep the rotational speed constant regardless of the load, the duty is increased so that the rotational speed becomes constant when the load is large, and the duty is decreased when the load is small.
[0049]
FIG. 7 is a characteristic diagram showing the relationship between duty and power output for operating the DC compressor 10 of the inverter control means 12 for each rotation speed of the DC compressor 10.
[0050]
The thick line shows the relationship between duty and power at high outside air temperature, and the thin line shows the relationship between duty and power at low outside air temperature.
[0051]
For example, if the rotational speed and the duty are known, the power can be predicted. For example, if the rotational speed is 2400 rps and the duty is m% at a high outside air temperature, the power is nW.
[0052]
This is because the DC motor has a motor current determined by the load, and the motor current can be predicted by the duty by changing the duty by the load and keeping the rotation speed constant. The input voltage is constant, for example, 100 V, depending on the duty. Electric power is required. Further, when the input voltage changes, a circuit for detecting the input voltage can be provided and corrected by the input voltage.
[0053]
Further, the difference in power with the same duty depending on the outside air temperature is due to the temperature of the DC motor. If the motor temperature is low, the efficiency is improved and the power is reduced.
[0054]
Reference numeral 13 denotes power calculation means, which calculates power consumption from the duty of the inverter control means 12 and the rotational speed command from the temperature determination means 11 and the outside air temperature from the outside air temperature detecting means 14 for detecting the outside air temperature around the storage. The power is calculated and output to the power amount calculation means 3 and the control means 18.
[0055]
The power amount calculation means 3 integrates the power from the power calculation means 13 and outputs the power consumption amount to the control means 18 and the power cost calculation means 15.
[0056]
When the accumulated time reaches 24 hours, the power cost calculator 15 multiplies the power consumption from the power calculator 3 by the power charge per unit from the power charge storage means 16, for example, 1 kwh by 25 yen. Output to the control means 18.
[0057]
Reference numeral 17 denotes a power charge input means for inputting a power charge per unit when the power charge per unit changes, and may be automatically input through a switch or the Internet. This input value is stored in the power cost storage means 16.
[0058]
The control unit 18 selects the power value from the power calculation unit 13, the power amount value from the power amount calculation unit 3, the power cost from the power cost calculation unit 15, or the internal temperature based on the signal from the switching unit 19, and the communication The communication means 6 transmits the signal to the display means 7.
[0059]
The operation of the refrigerator display device configured as described above will be described with reference to the flowchart of FIG.
[0060]
First, after turning on the power, the electricity bill input means 17 inputs the electricity bill per unit in step 20 and determines whether or not there is an input in step 21.
[0061]
If there is an input in step 21, the process proceeds to step 22 and is stored in the electricity bill storage means 16, and if there is no input, the process proceeds to step 23.
[0062]
When there is no input, the electricity bill storage means 16 stores the previously input value, and when there is no input, it stores a certain value, for example, 25 yen as an initial value.
[0063]
Next, in step 23, the temperature detection means 111 detects the temperature of the temperature sensor 108, in step 24 the temperature determination means 11 determines the internal temperature of the freezer compartment 103, and in step 25 the operating speed of the DC compressor 10 is determined. In step 26, the inverter control means 12 operates the DC compressor 10 and the fan 106.
[0064]
Next, in step 27, the power calculation means 13 inputs the duty value for operating the DC compressor 10 from the inverter control means 12, the operating rotational speed from the temperature determination means 11, and the outside air temperature from the outside temperature detection means 14, and in step 28. The power calculation means 13 calculates the power consumption.
[0065]
Next, at step 29, the power amount calculation means 3 integrates the power consumption amount.
[0066]
Next, in step 30, it is determined whether or not the electric energy calculation means 3 has integrated the electric energy for 24 hours. If the electric energy is integrated for 24 hours, the electric power consumption for one day is determined in step 31. Start integrating power consumption. The daily power consumption determined in step 31 is valid until the newly integrated power consumption is determined.
[0067]
In step 31, the power cost calculation means 15 calculates the daily power cost from the determined daily power consumption and the power cost per unit stored in the power cost storage means 16.
[0068]
If 24 hours are not integrated in step 30, the daily power consumption is not determined and the process proceeds to step 6.
[0069]
In step 32, the control means 18 determines whether or not the switching means 19 is displaying the temperature. If the temperature is displayed, the internal temperature is input from the temperature detecting means 111 in step 33 and the content is output to the communication means 6. To do.
[0070]
If the temperature is not displayed in step 32, it is determined whether the power is displayed or the amount of power is displayed in step 34. If the power is displayed, power is input from the power calculation means 13 in step 35, and the content is displayed. Output to the communication means 6.
[0071]
If the power amount display is not in step 34, it is determined in step 36 whether the power amount is displayed or the electricity bill is displayed. If the power amount is displayed, the power amount is input from the power amount calculation means 13 in step 37, The contents are output to the communication means 6, and if it is a power charge display, the power charge is input from the power charge calculation means 15 in step 38, and the content is output to the communication means 6.
[0072]
In step 39, the communication means 6 outputs the contents from the control means 18 to the display means 7, and in step 40, the display means 7 displays the transmitted contents.
[0073]
Thus, since the power is displayed, it is possible to inform the user of the current power consumption, and since the power is calculated from the rotation speed and the duty of the DC compressor 10, no current detection is required.
[0074]
Further, the power consumption amount can be calculated from the power and displayed to display the power amount of the storage, and the user can be informed of the power consumption amount for one day or one month.
[0075]
In addition, it calculates the electricity bill from the power consumption and the electricity bill per unit, and displays the electricity bill of the storage to display it, and can inform the user of the electricity bill for one day or one month. Even if the electricity bill changes, a new electricity bill can be entered and the correct electricity bill can be displayed.
[0076]
Further, since the display contents are transmitted by the communication means 6, the power and the power amount can be displayed even at a remote place.
[0077]
Further, the switching means 19 can select display contents that the user wants to know.
[0078]
(Embodiment 2 )
FIG. 8 shows the present invention. 2 FIG. 9 is a block diagram of a display device according to an embodiment of the present invention, and FIG. 2 It is a flowchart for demonstrating operation | movement of the display apparatus in FIG. In addition, the same code | symbol is provided to the structure same as each above-mentioned embodiment and the prior art, and the detailed description is abbreviate | omitted.
[0079]
Reference numeral 20 denotes power amount calculation means, which integrates the electric power from the power calculation means 13 and outputs it to the control means 23.
[0080]
Further, if integrated for 24 hours, the power consumption amount is output to the power amount storage means 21 and the power amount comparison means 22.
[0081]
The power amount storage means 21 stores the power consumption amount integrated for 24 hours by the power amount calculation means 20 and outputs the value to the power amount comparison means 22 and the control means 23.
[0082]
If there is an output from the power amount calculation means 20, the power amount comparison means 22 compares the value of the power amount storage means 21 with the power consumption amount from the power amount calculation means 20, and sets the value of the power amount storage means 21 yesterday. The current power amount is determined to be “more”, “same”, and “less” than yesterday with the power consumption amount from the power amount and power amount calculation means 20 as today's power amount, and is output to the control means 23.
[0083]
Based on the signal from the switching unit 24, the control unit 23 selects the power value from the power calculation unit 13, the power amount value from the power amount calculation unit 20, the comparison result from the power amount comparison unit 22, or the internal temperature. The communication means 6 transmits the signal to the display means 7.
[0084]
About the display apparatus of the refrigerator comprised as mentioned above, the operation | movement is demonstrated using the flowchart of FIG.
[0085]
First, after turning on the power, step 50 detects the temperature of the temperature sensor 108 with the temperature detection means 111, step 51 determines the internal temperature of the freezer compartment 103 with the temperature determination means 11, and step 52 determines the DC compressor 10. The inverter control means 12 operates the DC compressor 10 and the fan 106 at step 53.
[0086]
Next, at step 54, the power calculation means 13 inputs the duty value for operating the DC compressor 10 from the inverter control means 12 and the operating rotational speed from the temperature determination means 11, and the outside air temperature from the outside air temperature detection means 14, and the consumption at step 55. The power is calculated by the power calculation means 13.
[0087]
Next, at step 56, the power amount calculation means 20 integrates the power consumption amount.
[0088]
Next, in step 57, it is determined whether or not the electric energy calculation means 20 has integrated the electric energy for 24 hours. If the electric energy is integrated for 24 hours, the current electric energy is output to the electric energy comparison means 22 and the electric energy storage means 21 in step 58. The power amount comparison means 22 inputs yesterday's power amount from the power amount storage means 21 and determines whether the current power amount is “more”, “same”, or “less” than yesterday compared to today's power amount. And output to the control means 23.
[0089]
Next, at step 59, the power amount storage means 21 stores today's power amount output from the power amount calculation means 20 as yesterday's power amount, and the power amount calculation means 20 starts a new 24-hour power consumption amount from the next time. Starts accumulating. The comparison result in step 58 is valid for the next power amount comparison.
[0090]
If it is not integrated in step 57 for 24 hours, the process proceeds to step 60.
[0091]
In step 60, the control means 23 determines whether or not the switching means 24 is displaying a temperature. If the temperature is displayed, the internal temperature is input from the temperature detection means 111 in step 61 and the content is output to the communication means 6. To do.
[0092]
If the temperature is not displayed in step 60, it is determined whether the power is displayed or the amount of power is displayed in step 62. If the power is displayed, the power is input from the power calculating means 13 in step 63, and the content is displayed. Output to the communication means 6.
[0093]
If the power amount display is not displayed in step 62, it is determined whether the power amount is displayed or the comparison result is displayed in step 64. If the power amount is displayed, step 65 determines whether the current power amount is yesterday's power amount or yesterday's power amount. If it is today's power amount, the power amount is input from the power amount calculation means 20 in step 66, and the contents are output to the communication means 6. If yes, the power amount is stored in step 67. The power amount is input from the means 21 and the content is output to the communication means 6. If the result is a comparison result, the comparison result is input from the power amount comparison means 22 in step 68 and the content is output to the communication means 6.
[0094]
In step 69, the communication means 6 outputs the contents from the control means 23 to the display means 7, and in step 70, the display means 7 displays the transmitted contents.
[0095]
In the present embodiment, the description is based on the comparison result of the electric energy, but it does not change at all even if the electric power charges are compared and displayed.
[0096]
Thus, since the comparison result of the electric energy is displayed, the increase / decrease in the current electric energy with respect to the previous day or the increase / decrease in the electric energy of this month with respect to the previous month can be displayed, and the user can be notified of the change in the electric energy consumption. it can.
[0097]
In addition, since the amount of power to be displayed can be switched between yesterday's power amount and today's power amount, the actual power amount can be notified.
[0098]
【The invention's effect】
As described above, the invention described in claim 1 of the present invention is , D A DC compressor equipped with a C motor and a DC compressor are driven, and power calculation means for calculating power consumption from inverter control means for outputting the drive duty of the DC compressor, and power calculated by the power calculation means are output to the display means. Control means and display means for displaying the power by the output of the control means, it is possible to calculate the power without having to detect the current, display the power of the storage, and present the current power consumption to the user Can be informed.
[0099]
Claim 2 The invention described in 1 is provided with a power amount calculating means for calculating a power consumption amount from the power calculated by the power calculating means, and a control means for outputting the power amount calculated by the power amount calculating means to the display means. Yes, the amount of power in the storage can be displayed and the user can be informed of the amount of power consumed for one day or one month.
[0100]
Claim 3 The invention described in 1 is provided with an outside air temperature detecting means for detecting the outside air temperature around the storage, and a control means for correcting electric power with the outside air temperature detected by the outside air temperature detecting means. The power can be corrected and the accuracy of the power amount can be improved.
[0101]
Claim 4 The power amount storage means for storing the power amount, the power amount comparison means for comparing the power amount stored in the power amount storage means with the power amount calculated by the power amount calculation means, and the power amount comparison The control means for outputting the result of comparison by the means to the display means can display the increase / decrease in the current power amount relative to the previous day or the increase / decrease in the current power amount relative to the previous month. Can inform the amount change.
[0102]
Claim 5 The invention described in 1 is provided with a power cost storage unit that stores a power cost per unit, a power cost calculation circuit that multiplies the power amount calculated by the power amount calculation unit, and a control unit that outputs a multiplication result to the display unit. It can display the electricity bill.
[Brief description of the drawings]
FIG. 1 of the present invention Reference example 1 is a block diagram of the display device
FIG. 2 of the present invention Reference example 1 is a flowchart for explaining the operation of the display device in FIG.
FIG. 3 shows an embodiment of the present invention. 1 Block diagram of display device
FIG. 4 is an embodiment of the present invention. 1 Flowchart for explaining the operation of the display device
FIG. 5 shows an embodiment of the present invention. 1 Block diagram of inverter control means in
FIG. 6 shows an embodiment of the present invention. 1 Timing chart explaining the operation of the inverter control means in
FIG. 7 shows an embodiment of the present invention. 1 Chart showing the relationship between duty and power for each rotation speed
FIG. 8 shows an embodiment of the present invention. 2 Block diagram of display device
FIG. 9 shows an embodiment of the present invention. 2 Flowchart for explaining the operation of the display device
FIG. 10 is a block diagram showing a conventional refrigerator control device.
FIG. 11 is a flowchart showing a conventional refrigerator control device.
[Explanation of symbols]
1 Current detection means
2 Power calculation means
3 Electric energy calculation means
4 Control means
5 Switching means
6 Communication means
7 Display means
10 DC compressor
12 Inverter control means
13 Power calculation means
14 Outside air temperature detection means
15 Electricity cost calculation means
16 Electricity cost storage means
17 Electricity cost input means
18 Control means
19 Switching means
20 Electric energy calculation means
21 Electric energy storage means
22 Electric energy comparison means
23 Control means
24 switching means

Claims (5)

Determined in repository to store food or the like accommodated cooled, by driving the DC compressor and DC compressor equipped with DC motor, and the inverter control means to output a drive duty of the DC compressor, the operation and stop of the DC compressor And a temperature determining means for outputting the operation and operation speed and stop signal to the inverter control means, a power calculating means , a control means for outputting the power calculated by the power calculating means to the display means, and the control means of Ri Do display means for displaying the power by the output, the said power calculating means, characterized in that for calculating the power consumption from the working rotational speed from the temperature determination means and the duty value for driving the DC compressor from said inverter control means And storage . A power amount calculating means for calculating a power consumption amount from the power calculated by the power calculating means, a control means for outputting the power amount calculated by the power amount calculating means to the display means, and an electric energy by the output of the control means The storage of Claim 1 which displays. Control means for at ambient temperature for correcting the power detected by the outside air temperature detection means and the outside air temperature detecting means for detecting the outside air temperature around the storage box, to claim 1 for displaying the calculation result by the output of the control means Storage as described. Comparison between the power amount storage means for storing the power amount, the power amount comparison means for comparing the power amount stored in the power amount storage means with the power amount calculated by the power amount calculation means, and the power amount comparison means The storage according to claim 1 or 2 , wherein a comparison result is displayed by a control means for outputting the result to the display means and an output of the control means. A power cost storage unit that stores a power cost per unit, a power cost calculation circuit that multiplies the power amount calculated by the power amount calculation unit, a control unit that outputs a multiplication result to the display unit, and an output of the control unit The storage of Claim 2 or 4 which displays a power bill.

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