JPH09217974A - Cooler for showcase - Google Patents

Abstract

PROBLEM TO BE SOLVED: To manage the high freshness of goods, save energy, facilitate a maintenance and make the capacity of a refrigerating machine appropriate by generally and rationally controlling showcases and the refrigerating machine. SOLUTION: A general controller 34 which is provided between a group of showcases 1 and a refrigerating machine 6 and controls generally and rationally both the members comprises an operation factor computing part 3, a pressure setting value computing part 4 and a rotating speed command computing part 5. The operation factor computing part 3 obtains every constant time the operation factor of a solenoid valve for a constant time before the above constant time. The pressure setting value computing part 4 obtains a setting value (update) for a next constant time relative to the intake refrigerant pressure of a compressor 9 operated through an inverter 8 in the side of the refrigerating machine 6, based on the operation factor of the solenoid valve. The rotating speed command computing part 5 obtains a rotating speed command (update) for a next constant time relative to the compressor 9, based on a deviation between the obtained the setting value of the intake refrigerant pressure and an actual pressure.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a showcase cooling device which realizes high freshness management of products and energy saving by comprehensively and reasonably controlling a showcase and a refrigerator constituting a refrigeration cycle.

[0002]

2. Description of the Related Art A conventional example will be described with reference to FIGS. FIG. 15 is a block diagram showing a configuration of a conventional example. The conventional example is roughly divided into a showcase group 1 and a refrigerator 6. One showcase group 1 is a group in which all of the showcases 1A, 1B, 1C,... (Hereinafter referred to as 1A...) Are arranged side by side in a store to form one group. Each evaporator 2
A, a showcase controller 34A for on / off control of the flow of the refrigerant to the evaporator 2A, an electromagnetic valve (not shown) as an operation end for turning on / off the flow of the refrigerant, and a Temperature sensors 14A for measuring the temperature of the blown air. Here, the reason why the location where the air was blown out was selected as the temperature measurement location in the showcase was that the location was not affected by the quantity of stored products and that the temperature based on the control was another factor. This is because it is convenient for control because the change appears most precedence. The other refrigerator 6 includes a compressor 9, a condenser 31, a low-pressure pressure sensor 7 for measuring a suction refrigerant pressure of the compressor 9, and a compressor 9 based on a deviation between the measured pressure value and a set value thereof. A refrigerator controller 12 that performs on / off control is provided.

The evaporators 2A ... Are connected in parallel with each other, and the compressor 9 and the condenser 31 are connected in series with the parallel connection to form a refrigeration cycle. Each controller 3
4A... Controls the flow of the refrigerant to the corresponding evaporators 2A... Based on the deviation between the temperature signal from the corresponding temperature sensor 14A and the set value. The refrigerant is diverted from the compressor 9 after passing through the condenser 31 to flow to each evaporator 2A, or circulated so as to return to the compressor 9 after being prevented from flowing. Here, the control signal of each controller 34A ... Is schematically illustrated so as to be input to the preceding stage of the corresponding evaporator 2A ..., and it has been shown that the flow of the refrigerant is ON / OFF controlled (see FIG. 16 for details). reference).

FIG. 16 is a block diagram showing the structure of a conventional refrigeration cycle in detail. This refrigeration cycle includes a compressor 9 and a condenser 31 built in the refrigerator 6, an evaporator 2A built in each showcase 1A, a corresponding solenoid valve 33A and a temperature expansion valve 32A. Is done. The control operation of this refrigeration cycle is performed in the showcase 1A.
, The on / off control of the flow of the refrigerant to the evaporators 2A ... via the controller 34A ... Based on the deviation between the set value of the blown air temperature and the measured value by the temperature sensor 14A ... (see FIG. 15). It is to be. That is,
If the deviation is positive (measured value ≥ set value), the solenoid valve 3
3A ... open (ON), and the deviation is negative (measured value <
(Set value), the solenoid valves 33A ... Are closed (OFF)
Thus, the flow of the refrigerant to the evaporators 2A ... Is turned on / off. In the refrigerator 6, on / off control of the operation of the compressor 9 is performed via the controller 12 on the basis of the deviation between the set value of the suction refrigerant pressure of the compressor 9 and the value measured by the pressure sensor 7 in FIG. That is, the compressor 9 is turned on or off when the measured pressure value is equal to or more than the set value. Since this is on / off control, the set value here actually consists of upper and lower set values.

The operation of the conventional showcase refrigeration cycle will be described with reference to the time chart of FIG. In this figure, at time (1), since all the measured values of the blown air temperature of the showcase 1A by the temperature sensor 14A (not shown) are below the set value (lower limit), the controller 34A (not shown) is used. The solenoid valve 33A is closed (OFF). At this time, since the measured value of the pressure of the suction refrigerant by the pressure sensor (not shown) is equal to or lower than the set value (lower limit), the compressor is stopped, and the temperature of the blown air tends to increase. (2) At this point, the temperature of the air blown out of the showcase 1A rises and exceeds the set value (upper limit set value), so that the solenoid valve 33A opens (ON). At the same time, since the measured value of the pressure of the suction refrigerant becomes equal to or higher than the set value (upper limit), the compressor is operated. After that, the blow-out air temperature of the showcases 1B and 1C sequentially rises and becomes equal to or higher than the set value (upper limit), so that the solenoid valves 33B and 33C open. Are cooled by the refrigerator, and the temperature of each blown air drops. (3) At the point in time, the temperature of the air blown out of the showcase 1A first becomes lower than the set value, the solenoid valve 33A is closed, and subsequently, the solenoid valves 33B and 33C are sequentially closed. (4) At this point, all the solenoid valves are closed and the evaporator 2
A so-called pump-down operation is performed in which the refrigerant between A and the refrigerator is recovered by the refrigerator. As a result, at time (5), the measured value of the pressure of the suction refrigerant becomes equal to or lower than the set value (lower limit), and the compressor is stopped.

FIG. 18 shows the operation / stop of the compressor and the temporal change in the temperature of the air blown from the showcase.
Shown in (a) and (b). In FIG. 3A, the compressor is continuously operated (stopped) (on / off), and in FIG. 3B, the blown air temperature fluctuates up and down around a set value. It should be noted that the display of each set value of the upper limit and the lower limit is omitted.

[0007]

The conventional refrigeration cycle has the following problems. (1) The refrigerator is based on the measurement value of the pressure sensor, and the showcase 1A ... Is based on the measurement value of the temperature sensor 14A.
They are controlled independently of each other, and the measured values of the pressure sensor and the temperature sensor are not mutually exchanged for control.
Therefore, there is a problem in controlling the showcase refrigeration cycle including the showcase and the refrigerator in a comprehensive and rational manner so that the showcase refrigeration cycle can operate sufficiently efficiently. (2) Generally, the capacity of a refrigerator is selected based on the required load in the summer, so the refrigerating capacity becomes excessively large compared to the showcase load outside the summer, and in part, wasteful power consumption occurs and low power consumption occurs. Since the operation becomes efficient and the compressor is operated and stopped more frequently, the problem arises that the temperature of the air blown out from the showcase fluctuates, that is, the fluctuation range increases. (3) If a bad cooling condition occurs due to load fluctuations or environmental changes after the showcase is installed and initially adjusted, it is necessary to manually adjust the set value of the blowout air temperature for that showcase. Maintenance of was troublesome. (4) Since it takes time to cool down after defrosting, that is, to pull down, there is a possibility that the freshness of the product may deteriorate during that time. (5) Since the corresponding showcases are operated according to the blown air temperature, it is possible that all the showcases are operated at the same time, that is, the showcase group is operated collectively. Therefore, the capacity of the refrigerator is selected on the assumption that the showcase group is collectively operated at the peak load in the summer. As a result, the selected refrigerator actually tends to have an excessive capacity and thus an excessive cost.

The problem to be solved by the present invention is to solve the above problems of the prior art and to comprehensively and rationally control the showcase and the refrigerator constituting the refrigeration cycle, and thus It is to provide a showcase cooling device that realizes high freshness management, energy saving, easy maintenance, and proper refrigerating machine capacity.

[0009]

SUMMARY OF THE INVENTION According to the present invention, a solenoid valve is used to control the flow of refrigerant to an evaporator based on the deviation of the air temperature at a predetermined location in the main body, for example, the air temperature at a blowout location or a product storage location and its set value. One or more showcases that are turned on and off via a common case, a common refrigerator that constitutes a refrigeration cycle with the showcases, and an integrated controller that controls the showcases and the refrigerators. (1), (2), or (3). (1) An operation rate calculation unit that obtains a solenoid valve operating rate, which is the ratio of the on time of the solenoid valve to the previous constant time, at a certain time interval; built in the refrigerator based on the obtained solenoid valve operating rate And a pressure set value calculation unit that obtains a set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor, the inverter compression based on the deviation between the obtained suction refrigerant pressure set value and the actual pressure. A rotation speed command calculation unit for obtaining a rotation speed command for the next fixed time to the machine;
Is provided. (2) Temperature drop that determines the average drop rate of the air temperature at the specified location in the main body of the corresponding showcase when each solenoid valve is repeatedly turned on and the flow of refrigerant is turned on at fixed time intervals before that. A speed calculation unit; a pressure set value calculation unit that calculates a set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor incorporated in the refrigerator, based on the obtained average drop speed of each air temperature. And a rotation speed command calculation unit for calculating a rotation speed command for the next fixed time for the inverter compressor based on the deviation between the obtained set value of the suction refrigerant pressure and the actual pressure. (3) An on / off cycle calculator that calculates the average on / off cycle when each solenoid valve is repeatedly turned on / off at a fixed time before that; and the calculated average of each solenoid valve. A pressure set value calculation unit for obtaining a set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor incorporated in the refrigerator, based on the on / off cycle; and the obtained set value of the suction refrigerant pressure And a rotation speed command calculation unit for obtaining a rotation speed command for the next constant time for the inverter compressor based on the deviation from the actual pressure.

Further, according to the present invention, immediately after the operation in the defrosting mode, the blown air temperature of all showcases,
Or, it is equipped with a high rotation speed command unit that commands a predetermined high rotation speed to the inverter compressor of the refrigerator until the temperature of the product storage location falls below the set value, or the stored products common to all showcases It is preferable that an initial value setting unit that determines an initial value of the pressure setting is provided in advance for the pressure setting value calculation unit based on the type.

The present invention also provides one or more showcases for controlling the flow of the refrigerant to the evaporator on / off via an electromagnetic valve based on the deviation between the temperature of the blown air and its set value. In a showcase cooling device including a common refrigerator that constitutes a refrigeration cycle and a temperature sensor that measures the temperature of a product storage location of each showcase; and the set value of the blown air temperature is corrected based on the measured temperature. And a temperature set value correction unit.

Furthermore, according to the present invention, when a predetermined number or more of solenoid valves are to be turned on at the same time, the solenoid valves which should reach the predetermined number are turned off until one of the solenoid valves which is already on is turned off. Do not turn on, keep it in the off state, hold the showcase solenoid valve in the off state in the order that the temperature of the product storage location is close to the set value, and show the solenoid of the showcase based on a predetermined priority The valve is kept in the OFF state, and the solenoid valves are kept in the OFF state in the ascending order of the operation rate, and at the same time, the number of operating solenoids restriction unit that keeps the solenoid valves in the ON state below a predetermined number is provided. It is preferable to adopt the configuration.

Therefore, in the present invention, the integrated controller operates as follows. (1) Calculate the solenoid valve operating rate, which is the ratio of the solenoid valve on-time to the previous constant time, by the operating rate calculation unit, or (2) by the temperature drop rate calculation unit Before each solenoid valve is repeatedly turned on for a certain period of time to turn on the flow of the refrigerant, calculate the average drop rate of the air temperature at the specified location in the body of the corresponding showcase, or (3) ON / OFF cycle In short, the load condition of the showcase is obtained by calculating the average on / off period when each solenoid valve is repeatedly turned on / off at a constant time before the constant time by the calculation unit. Next, by the pressure set value calculation unit,
Based on the solenoid valve operating rate, that is, the load condition of the showcase, the set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor incorporated in the refrigerator is obtained. Next, the rotation speed command calculation unit obtains a rotation speed command for the next fixed time based on the deviation between the set value of the suction refrigerant pressure and the actual pressure. The inverter compressor can be rotated by this finally obtained rotation speed command. In this way, the information on the showcase load assumed based on the operation of the solenoid valve on the showcase side and the information on the suction refrigerant pressure of the inverter compressor on the refrigerator side are collected to determine the ambient temperature, humidity, etc. Comprehensive and rational control of refrigerator operation is performed so that it can flexibly respond to changes in the environment, and that the showcase load is approximately equal to the refrigerating capacity of the refrigerator.

Further, according to the present invention, the temperature set value correction unit can correct the set value of the blown air temperature based on the measured temperature of the product storage portion of each showcase, that is, the actual cooling condition of the product. . Further, in the present invention, immediately after the defrosting operation, by the high rotation speed command unit, the blowout air temperature of all the showcases becomes equal to or lower than the set value, or the temperature of the product storage location becomes equal to or lower than the set value. Until then, a predetermined high rotation speed can be instructed to each inverter compressor. Further, the initial value setting unit can predetermine the initial value of the pressure setting for the pressure setting value calculation unit based on the type of stored product common to all showcases.

Furthermore, according to the present invention, when the predetermined number of solenoid valves or more should be turned on at the same time by the operating number limiting unit provided in the preceding stage of the general controller,
The number of solenoid valves that are turned on at the same time can be suppressed to less than a predetermined number by any method. The solenoid valves that should reach the predetermined number are kept in the off state without being turned on until one of the solenoid valves that is already in the on state is turned off. At the same time, among the solenoid valves to be turned on, the solenoid valves of the showcase are kept off in the order in which the temperature of the product storage location is closer to the set value. Among the solenoid valves that should be turned on at the same time, the solenoid valves of the showcase are kept in the off state based on a predetermined priority. At the same time, among the solenoid valves to be turned on at the same time, the solenoid valves are kept in the off state in ascending order of the operation rate.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION As an embodiment of the present invention, a first embodiment will be described with reference to the block diagram showing the configuration of FIG. In FIG. 1, an integrated controller 34 for newly comprehensively and rationally controlling the showcase group 1 and the refrigerator 6, which is the same as the conventional one, is interposed.
Is provided. The integrated controller 34 includes an operation rate calculation unit 3, a pressure set value calculation unit 4, and a rotation speed command calculation unit 5.

The operating rate calculation unit 3 obtains the electromagnetic valve operating rate, which is the ratio of the on-time of each solenoid valve 33A ... (See FIG. 16) to the preceding constant time at fixed time intervals. The pressure set value calculation unit 4 calculates a set value for the next fixed time with respect to the suction refrigerant pressure of the compressor 9 operated via the inverter 8 on the side of the refrigerator 6 based on the determined solenoid valve operation rate. (Update). The rotation speed command calculation unit 5 calculates a rotation speed command (update) for the next fixed time for the compressor 9 based on the obtained deviation between the set value of the suction refrigerant pressure and the actual pressure.

The technical meaning of the pressure set value calculation unit 4 will be described below with reference to FIGS. FIG. 2 is a relationship diagram of the refrigerating function power, the showcase load, the power consumption, and the pressure set value (of the refrigerant sucked into the compressor). The horizontal axis shows the pressure setting value, and the vertical axis shows the refrigeration function power, showcase load, and power consumption. Both the refrigeration function power and the power consumption decrease as the pressure setting value increases. Here, the refrigeration functional force shifts in the arrow direction, that is, in the upper right and lower left directions, depending on the level of the ambient temperature (that is, with the ambient temperature as a parameter). The showcase load shifts in the arrow direction, that is, in the upper and lower directions according to the ambient temperature and humidity, but is constant regardless of the pressure set value. What can be said from the above is that the pressure setting value that effectively and exactly the power consumption for cooling the showcase, that is, the minimum required pressure setting is the pressure setting when the relationship of refrigeration function power = showcase load is established. It is the limit value.

The pressure setting limit value fluctuates according to changes in the ambient temperature of the refrigerator and the ambient temperature / humidity of the showcase. Fig. 3 shows changes in each value according to the four seasons. (A) is a change diagram of ambient temperature and humidity, (b) is a change diagram of pressure set value, (c)
[Fig. 3] is a change diagram of the refrigerating capacity / showcase load. FIG.
As in (a), the ambient temperature of the refrigerator fluctuates sinusoidally depending on the four seasons, but since the showcase is originally installed in an air-conditioned room, the ambient temperature Humidity is almost constant throughout the four seasons. Same figure
When the set pressure value is updated (changed) according to the four seasons so that it becomes the above-mentioned limit value as shown by the solid line in (b), the refrigeration function power is almost constant throughout the four seasons as shown by the solid line in (c). It will be constant, and will be slightly higher than the showcase load, which is almost constant throughout the four seasons. Note that the showcase load changes according to the ambient temperature and humidity (hence, according to the four seasons) as described above, but since it is small, it is shown as constant in the figure. On the other hand, if the pressure setting value is constant throughout the four seasons as indicated by the dotted line in the same figure (b), the refrigeration function power changes according to the four seasons, as indicated by the dotted line in the same figure (c). Will be done.

Therefore, as shown in FIG. 3 (c), the optimum pressure setting value that minimizes the amount of power consumption, that is, the pressure setting limit value is conclusively small in summer and large in winter. , Spring and Autumn are set in between. In other words, in FIG. 2, the refrigeration function power / pressure set value line shifts to the lower left when the ambient temperature of the refrigerator increases in summer, and one showcase load / pressure set value line indicates the showcase ambient temperature / Since the humidity is almost constant throughout the four seasons, the intersection shifts to the left (direction where the pressure setting value decreases), and conversely in winter, the intersection moves to the right (direction where the pressure setting value increases) for the same reason. ).

As described above, in order to optimally update the pressure set value so that the power consumption amount becomes the minimum necessary, it is sufficient to know the refrigerating function force and the showcase load under each environmental condition. Is difficult to actually measure. Therefore, in practice, it is judged whether the refrigerating function power is insufficient, appropriate, or excessive while observing the balance between the refrigerating function power and the showcase load, and the pressure set value is optimally updated based on this. In addition, the balance between the refrigeration function and the showcase load is determined based on the operating rate of the solenoid valve of the showcase. That is, when the operation rate of the solenoid valve is low, the refrigerating function is excessive with respect to the showcase load, and when the operation rate of the solenoid valve is high, the refrigerating function is insufficient with respect to the showcase load, and the operation rate of the solenoid valve is low. When appropriate, it is determined that the refrigeration function is appropriate for the showcase load.
It should be noted that it is empirical to judge whether the operating rate of the solenoid valve is high, low or appropriate. This will be described below.

FIG. 5 is a pressure set value / showcase operating rate correspondence diagram relating to the update of the pressure set value. This is an empirical rule for updating the pressure set value, and this content is implemented by the pressure set value calculation unit 4 in FIG. In other words, (1) If the operating rate of at least one showcase (solenoid valve) is 90% or more, it is determined that the refrigeration function is insufficient, and the pressure set value is reduced (updated) by 0.01 MPa (0.1 kg / cm ² ). To increase the refrigeration function. (2) All showcase (solenoid valve) operating rates are 40 to 90
%, It is determined that the refrigeration function is appropriate, and the pressure set value is maintained as it is. (3) If all showcase (solenoid valve) operating rates are 90% or less and at least one unit is 40% or less, the refrigeration function is judged to be excessive, and the pressure set value is increased by 0.01 MPa (updated). Reduce the refrigeration function.

By the way, when the solenoid valve is repeatedly turned on and the flow of the refrigerant is turned on instead of judging the balance between the refrigerating function power and the showcase load based on the operating rate of the showcase solenoid valve as described above. It is also possible to make a judgment based on the average drop rate of the air temperature at a predetermined location in the body of the corresponding showcase, or based on the average on / off cycle when the solenoid valve is repeatedly turned on / off. Is. These other determination methods will be described below.

In the method of judging the balance between the refrigerating function power and the load of the showcase based on the average drop rate of the air temperature at a predetermined location in the body of the showcase, the general controller 34X of FIG. 6 is used. This general controller 34X is a first modified example of the general controller 34 in FIG. 1, and a temperature lowering speed calculator 3X is used instead of the solenoid valve operation rate calculator 3 in the general controller 34. Based on the operating signal of the solenoid valve of each showcase and the temperature signal of the blown air, the temperature drop speed calculating unit 3X repeatedly turns on the solenoid valve at a certain time before the certain time, and turns on the flow of the refrigerant. The average descent speed of the temperature of the blown air of the corresponding showcase when turned on is determined. The average descent rate may be calculated for the air temperature signal of the product storage location instead of the temperature signal of the blown air.

By the way, it is possible to judge whether the refrigerating function is excessive or insufficient with respect to the showcase load, depending on whether the average drop rate of the temperature of the blown air is high or low. The judgment is shown in FIG. It is done based on experience. FIG. 9 is a diagram showing the relationship between the pressure set value and the blown air temperature drop rate relating to the update of the pressure set value, and this content is executed by the pressure set value calculation unit 4 in FIG. That is, (1) If at least one of the units has a descent speed below the lower limit value, it is determined that the refrigerating function is insufficient, and the pressure setting value is lowered to increase the refrigerating function. (2) If the descent speed is within the set range for all showcases, it is determined that the refrigeration function is appropriate, and the pressure set value is maintained as it is. (3) If at least one of the units has a descent speed equal to or higher than the upper limit value, it is determined that the refrigerating function is excessive, and the set pressure is increased to decrease the refrigerating function.

In the method of judging the balance between the refrigerating function power and the showcase load based on the average on / off cycle when the showcase solenoid valve is repeatedly turned on / off,
The integrated controller 34Y shown in FIG. 7 is used, which is shown in FIG.
In the second modified example of the integrated controller 34, the on / off cycle calculation unit 3Y is used in place of the solenoid valve operating ratio calculation unit 3 in the integrated controller 34. The on / off cycle calculation unit 3Y calculates an average on / off cycle when each solenoid valve is repeatedly turned on / off at a certain time before a certain time, based on the solenoid valve operation signal of each showcase. You can ask.

Now, it is possible to judge whether the refrigerating function is excessive or insufficient with respect to the showcase load, depending on whether the average on / off cycle is small or large. The judgment is based on the rule of thumb shown in FIG. It is done based on. FIG. 10 is a pressure set value / on / off cycle correspondence diagram of the solenoid valve related to the update of the pressure set value. This content is shown in FIG.
Will be implemented in. In other words, (1) If the on / off cycle of at least one unit exceeds the upper limit, it took more time for cooling. Therefore, it was determined that the refrigeration function was insufficient, and the pressure setting value was lowered to reduce the refrigeration function. Increase power. (2) For all showcases, if the ON / OFF cycle is within the set range, the refrigeration function is judged to be appropriate and the pressure set value is maintained as it is. (3) If the ON / OFF cycle of even one unit is below the lower limit value, cooling was performed for that much time, so it was judged that the refrigeration function power was excessive, and the pressure setting value was increased to increase the refrigeration function power. To reduce.

By the way, in order to judge whether the refrigeration function is excessive or insufficient with respect to the showcase load, it is essential to look at the rate of decrease of the air temperature and to look at the on / off cycle of the solenoid valve. Is the same. In reality, the ease of detection and calculation is a problem, and in that respect the on / off of the solenoid valve
It is better to look at the off cycle. As described above, the pressure set value is calculated by the pressure set value calculation unit 4, but in order to further enhance the freshness management of the stored product, the initial value of the stored product is set to the ice level. Frozen foods such as cream, meat and fresh fish, daily products such as dairy products,
It is desirable to use appropriate combinations based on whether fruits or vegetables such as vegetables and fruits, that is, depending on the intended use. With this initial value setting, it is possible to quickly cool to each optimum temperature. A method of determining the initial value of this pressure setting will be described below.

Therefore, the total controller 34 of FIG.
Z is used. This integrated controller 34Z is shown in FIG.
In the third modified example of the integrated controller 34, the initial value setting section 40 is provided in the integrated controller 34 before the pressure set value calculation section 4. This initial value setting unit 40
Based on the type of stored product that is common to all showcases, that is, use, for example, the sign key corresponding to the type or use of the stored product is operated to predetermine the initial value of the pressure setting for the pressure set value calculation unit 4. You can The rule of thumb regarding this initial value setting is shown in the initial value / type of stored product correspondence diagram of the pressure setting in FIG. In the figure, the types (uses) of stored products are divided into 6 stages: frozen, chilled, iced temperature, meat, fresh fish, daily products, and fruits and vegetables, and the initial value of pressure setting is the lowest of "frozen" at the left end. Value, for example 1.0 Kg / cm ² (operating temperature −
(Corresponding to 18 ° C) to the maximum value of "fruits and vegetables" on the far right, for example 2.5 Kg / cm ² (corresponding to a working temperature of 5-10 ° C). Code keys are provided corresponding to the above six steps.

The structure of the compressor rotation speed command calculation unit 5 will be described with reference to the block diagram showing the structures of the rotation speed command calculation unit 5 and the refrigerator 6 in FIG. In the figure, a rotation speed command calculator 5 includes a deviation means indicated by a circle for obtaining a deviation between a pressure set value input from the preceding stage and a pressure measurement value from the pressure sensor 7 of the refrigerator 6, and a PID calculator 10.
Consists of The pressure deviation is converted into a rotational speed command for the compressor via the PID calculator 10 and transmitted to the compressor 9 via the inverter 8 on the side of the refrigerator 6 to change the rotational speed. The suction refrigerant pressure of the compressor 9 is fed back to the deviation means of the rotation speed command calculation section 5 via the pressure sensor 7, and the negative pressure targeting the input pressure setting value is set here.
A feedback control circuit is formed. The number of revolutions of the compressor is controlled so that the average value decreases as the pressure setting value increases and the average value increases as the pressure setting value decreases.

As a result, the pressure of refrigerant sucked into the compressor, the number of revolutions of the compressor, and the temperature of blown air (in the showcase) are as shown in the time charts of FIGS. 4 (a), 4 (b) and 4 (c), respectively. . As shown in FIG. 4 (a), the compressor suction refrigerant pressure fluctuates according to the pressure setting value. Correspondingly, as shown in FIG. 4 (b), the average value of the compressor rotational speed, which changes finely, decreases when the pressure setting value becomes high and rises when the pressure setting value becomes low. As a result of the operation such that the showcase load and the refrigeration function power are approximately equal to each other, it is possible to minimize the power consumption. Further, the rotation speed command of the compressor is issued according to the pressure set value, and the frequency of operation / stop of the compressor becomes lower than that of the conventional example. As a result, the temperature of the air blown out from the showcase is reduced because the amount of control overshoot is reduced.
The fluctuation range centered on the set value can be suppressed smaller than that of the conventional example (see FIG. 4 (c) and FIG. 12 (b)). In the first embodiment, a solution to the "problems to be solved by the invention" (1) and (2) is incorporated.

The second embodiment will be described with reference to FIG. 13 which is a block diagram showing the structure thereof. This second
In the embodiment, in addition to the first embodiment, a solution to "problems to be solved by the invention" (3), (4), (5) is inserted. That is, with respect to the problem (3), it becomes easy to adjust the blow-off air temperature set value when a showcase in which the cooling state is bad due to load fluctuations or environmental changes occurs. Task
In contrast to (4), the time required for return cooling after defrosting, that is, pull-down, is shortened, and deterioration of product freshness during that period is prevented. Task
For (5), limit the number of showcases operating simultaneously to rationalize the selected capacity of the refrigerator so that it does not become excessive.

In the second embodiment of FIG. 13, the first of FIG.
The parts added to the embodiment are the temperature sensor 15A for measuring the temperature of the product storage location of each showcase, the temperature set value correction unit 21, and the problem (4) as a solution to the problem (3).
The mode switch 22 and the high rotation speed command unit 23 as a solution to the above problem, and the simultaneous operation limiting unit 24 as a solution to the problem (5). These will be sequentially described below.

The temperature set value correction unit 21 measures the temperature of the product storage portion of each showcase 1A ... Through the respective temperature sensors 15A ... And the actual cooling degree of the product based on each measured value. Figure out Next, the set value of the blown air temperature for the controllers 34A ... Is automatically corrected accordingly. The rule (empirical rule) for this correction is shown in FIG.

In FIG. 14, the product storage location temperature is
(1) If the set value of blown air is + 5 ° C or higher, (2) If the set value is + 2 ° C or lower, (3) In other cases, it is divided into three, and blown air is adjusted according to each case. Correct the temperature setting value as follows. In the case of (1), the initial set value is -1 ° C, in the case of (2), the initial set value is + 1 ° C, and in the case of (3), the initial set value is kept.
By using the temperature set value correction unit 21, the troublesomeness of the conventional manual correction is remarkably improved.

After the so-called defrosting operation for removing the frost adhering to each showcase with respect to the normal operation, it is necessary to perform an operation of rapidly performing return cooling, that is, pulling down, in order to manage high freshness of the product. is there. Returning to FIG. 13, a mode switch 22 for switching between the “normal operation mode” and the “operation mode after defrosting” is provided at the subsequent stage of the showcase group 1. Therefore, the operation rate signal of each solenoid valve is sent to the general controller 34 side in the “normal operation mode” via the mode switch 22 and to the high rotation speed command unit 23 in the “operation mode after defrosting”. It is switched to the side and sent out. In the high rotation speed command unit 23, immediately after the defrosting operation, until the blowout air temperatures of all the showcases become equal to or lower than their respective set values, or until the temperatures of the product storage locations become equal to or lower than their respective set values, It is possible to instruct the inverter compressor of a predetermined high rotation speed for quick freezing. By this quick freezing, each showcase realizes a return cooling after defrosting, that is, a reduction in pull-down time, and it is possible to prevent deterioration of product freshness during that time.

The simultaneous operation number limiting unit 24 is provided between the mode switch 22 and the general controller 34, and the solenoid valve 3
3A (that is, showcase 1A ...) is restricted from being turned on at the same time. As stated above, the purpose of the selection is that the capacity of the refrigerator is selected on the assumption that the showcase group is operated at the peak load in summer, and as a result, the selected refrigerator actually has excessive capacity and cost. This is because Although it has been described here that all of the solenoid valves are simultaneously turned on, it is generally a broad measure to limit at least a predetermined number of solenoid valves from being on at the same time. The simultaneous operation number limiting unit 24 is configured to take any one of the following operations. That is, when all the solenoid valves should be in the ON state at the same time, stop the previous solenoid valve that should reach the total number without turning on until one of the solenoid valves that is already in the ON state becomes the OFF state. The temperature of the product storage location is close to the set value, that is, the comparatively cold showcase solenoid valve is kept in the OFF state, or based on a predetermined priority, that is, the importance of the stored product is set. In consideration of this, the solenoid valve of the showcase is kept in the OFF state, or the operating rate record is low, that is, the cooling condition of the product is relatively good and the solenoid valve of the showcase that has been operating for a short time in the past is kept in the OFF state. Or Thus, it is possible to prevent all the solenoid valves (showcases) from being turned on at the same time. Here, the simultaneous operation number limiting unit 24 corresponds to the operating number limiting unit in the invention.

[0038]

According to the present invention, the following excellent effects can be expected. (1) Showcase load estimated based on each solenoid valve operating rate, average drop rate of air temperature at a predetermined location in the body of the showcase, or average solenoid valve on / off cycle Information on the refrigerator and the information on the refrigerant pressure sucked into the inverter compressor on the refrigerator side are collected, and the operation of the refrigerator is comprehensive and rational so that the showcase load is approximately equal to the refrigerator capacity. Control is performed. Therefore, it is possible to cope with environmental changes such as ambient temperature and humidity, and it is possible to suppress the power consumption of the refrigerator to a necessary minimum and save energy. In addition, since the inverter compressor is rotated at an appropriate number of revolutions, the frequency of operating and stopping the compressor is reduced, and it is possible to reduce variations in the temperature of blowout air, for example, fluctuations in blowout air temperature. Therefore, high freshness management of products can be realized.

(2) Since the set value of the blown air temperature can be automatically corrected on the basis of the measured temperature of the product storage portion of each showcase, that is, the actual cooling condition of the product, the freshness of the product can be managed. In addition to being performed well, the time and effort required for the correction can be saved and maintenance can be facilitated as compared with the conventional manual correction. (3) Immediately after the operation in the defrost mode, until the temperature of the air blown out from all showcases falls below the set value,
Alternatively, the inverter compressor can be instructed at a predetermined high rotational speed until the temperature of the product storage locations of all showcases falls below the set value, so the pull-down time after operation in defrost mode In other words, the return cooling time can be shortened and the product freshness management can be supported.

(4) The pressure is preset based on the types of stored products common to all showcases, such as frozen foods such as ice cream, meat and fresh fish, daily products such as dairy products, fruits and vegetables such as vegetables and fruits. Since the initial value of the pressure setting can be determined for the value calculation unit, it is possible to quickly cool to the optimum temperature according to each stored product (use), and it is possible to support the freshness management of each product.

(5) Since the number of solenoid valves that are in the ON state at the same time can be suppressed to less than a predetermined number, that is, the maximum power consumption during peak load in the summer of the showcase group can be limited,
Therefore, the capacity of the refrigerator can be suppressed to be selected, and the cost of the device can be reduced, and the space and energy of the device can be saved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a first embodiment according to the present invention;

[Fig. 2] Relationship diagram of refrigeration power, showcase load, power consumption and pressure set value

[Fig. 3] Regarding changes in each value according to the four seasons, (a) is a change diagram of ambient temperature and humidity, (b) is a change diagram of pressure set value, and (c) is a change diagram of refrigerating capacity and showcase load.

[Fig. 4] Regarding time-dependent changes of each value, (a) is a time chart of compressor suction refrigerant pressure, (b) is a time chart of compressor rotation speed, and (c) is a time chart of blowout air temperature.

FIG. 5: Corresponding diagram of pressure set value / showcase operating rate related to update of pressure set value

FIG. 6 is a block diagram showing a first modification of the integrated controller.

FIG. 7 is a block diagram showing a second modification of the integrated controller.

FIG. 8 is a block diagram showing a third modified example of the general controller.

FIG. 9: Corresponding diagram of pressure set value / blow-off air temperature drop rate related to update of pressure set value

FIG. 10: Corresponding diagram of pressure set value / on / off cycle of solenoid valve related to update of pressure set value

[Fig. 11] Correspondence diagram of initial value of pressure setting / type of stored product

FIG. 12 is a block diagram showing a configuration of a compressor rotation speed command calculation unit and a refrigerator.

FIG. 13 is a block diagram showing the configuration of a second embodiment.

FIG. 14 is a correspondence diagram of blown air temperature set value / product storage location temperature related to correction of blown air temperature set value.

FIG. 15 is a block diagram showing a configuration of a conventional example.

FIG. 16 is a block diagram showing the configuration of a refrigeration cycle of a conventional example in detail.

FIG. 17 is a time chart showing the operation of the conventional refrigeration cycle.

FIG. 18 is a time chart of compressor start / stop, and (b) is a time chart of blown air temperature with respect to the time change of each value in the conventional example.

[Explanation of symbols]

1 Showcase group 1A, 1B, 1C Showcase 2A, 2B, 2C Evaporator 3 Operating rate calculator 3X Temperature drop rate calculator 3Y ON / OFF cycle calculator 4 Pressure set value calculator 5 Rotation speed command calculator 6 Refrigeration Machine 7 Pressure sensor 8 Inverter 9 Compressor 10 PID calculator 14A, 14B, 14C Temperature sensor (blowing air) 15A, 15B, 15C Temperature sensor (product storage location) 21 Temperature setting value correction unit 22 Mode switch 23 High rotation speed Command part 24 Simultaneous operation number limiting part 31 Condenser 32A, 32B, 32C Temperature expansion valve 33A, 33B, 33C Solenoid valve 34, 34X, 34Y, 34Z General controller 34A, 34B, 34C Controller (showcase individual) 40 Initial value setting Department

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yukimasa Tachibana 1-1, Tanabe Nitta, Kawasaki-ku, Kawasaki-shi, Kanagawa Fuji Electric Co., Ltd.

Claims (11)

[Claims] 1. A showcase for controlling the flow of a refrigerant to an evaporator on / off via an electromagnetic valve based on a deviation between an air temperature at a predetermined position in a main body and a set value thereof;
It consists of a common refrigerator that composes this and the refrigeration cycle, and an integrated controller that controls these showcases and refrigerators. This integrated controller is the ratio of the ON time of the solenoid valve to the fixed time before that at fixed intervals. And an operation rate calculation unit for obtaining an electromagnetic valve operation rate, which is a set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor incorporated in the refrigerator, based on the obtained operation rate of the solenoid valve. A pressure set value calculation unit; based on a deviation between the obtained set value of the suction refrigerant pressure and the actual pressure,
And a rotation speed command calculation unit that obtains a rotation speed command for the next fixed time to the inverter compressor, the showcase cooling device. 2. One or more showcases for controlling the flow of refrigerant to an evaporator on / off via an electromagnetic valve based on a deviation between an air temperature at a predetermined location in the main body and a set value thereof;
It consists of this and a common refrigerator that constitutes the refrigeration cycle, and an integrated controller that controls these showcases and refrigerators.This integrated controller repeatedly turns on each solenoid valve at fixed time intervals before that. And a temperature drop rate calculation unit that obtains an average drop rate of the air temperature at a predetermined location in the body of the corresponding showcase when the flow of the refrigerant is turned on; based on the obtained average drop rate of each air temperature A pressure set value calculation unit for obtaining a set value for the next fixed time with respect to the suction refrigerant pressure of the inverter compressor built in the refrigerator; and a deviation between the obtained set value of the suction refrigerant pressure and the actual pressure. Based on the inverter compressor, a rotation speed command calculation unit that obtains a rotation speed command for the next fixed time; 3. One or more showcases for controlling the flow of refrigerant to an evaporator on / off via an electromagnetic valve based on a difference between an air temperature at a predetermined location in the main body and a set value thereof;
It consists of this and a common refrigerator that constitutes the refrigeration cycle, and an integrated controller that controls these showcase and refrigerator.This integrated controller repeatedly turns on and off each solenoid valve at a fixed time before that. An on / off cycle calculation unit for obtaining an average on / off cycle when turned off; and a refrigerant sucked into an inverter compressor incorporated in a refrigerator based on the obtained average on / off cycle of each solenoid valve. A pressure set value calculation unit for obtaining a set value for the next fixed time with respect to the pressure; and for a next fixed time for the inverter compressor based on the deviation between the obtained set value of the suction refrigerant pressure and the actual pressure. A rotation speed command calculation unit for obtaining a rotation speed command, and a showcase cooling device. 4. The apparatus according to any one of claims 1 to 3, wherein, immediately after the operation in the defrosting mode, the temperature of blow-off air of all the showcases is kept below the set value. A showcase cooling device comprising a high rotation speed command unit for instructing an inverter compressor to have a predetermined high rotation speed. 5. The apparatus according to any one of claims 1 to 3, wherein immediately after the operation in the defrosting mode, refrigeration is performed until the temperature of the product storage locations of all showcases is below the set value. A showcase cooling device comprising a high rotation speed command section for instructing a predetermined high rotation speed to an inverter compressor of the machine. 6. The apparatus according to any one of claims 1 to 5, wherein an initial value of the pressure setting is determined in advance for the pressure setting value calculation unit based on the type of stored products common to all showcases. A showcase cooling device comprising an initial value setting unit. 7. The flow of the refrigerant to the evaporator is turned on via a solenoid valve based on the deviation between the temperature of the blown air and its set value.
In a showcase cooling device comprising one or more showcases controlled to be turned off and a common refrigerator constituting a refrigeration cycle, a temperature sensor for measuring the temperature of a product storage location of each showcase; and its measurement A showcase cooling device, comprising: a temperature set value correction unit that corrects the set value of the blown air temperature based on the temperature. 8. The apparatus according to claim 1, wherein when a predetermined number or more of the solenoid valves should be turned on at the same time, the solenoid valves that should reach the predetermined number are already turned on. A showcase cooling device, comprising: an operating number limiting unit that keeps the solenoid valves in an off state without turning on until one of the solenoid valves becomes an off state, and at the same time keeps the number of solenoid valves in the on state below a predetermined number. 9. The apparatus according to any one of claims 1 to 7, wherein when a predetermined number of solenoid valves or more should be turned on at the same time, the temperature of the product storage location is close to the set value. A showcase cooling device, comprising: an operating number limiting unit for sequentially keeping the solenoid valves of the showcase in an off state and simultaneously keeping the number of solenoid valves in an on state below a predetermined number. 10. The apparatus according to claim 1, wherein when a predetermined number or more of solenoid valves are to be turned on at the same time, the solenoid of the showcase based on a predetermined priority order among them. A showcase cooling device, comprising: an operating number limiting unit that keeps the valves in an off state and simultaneously keeps the number of solenoid valves in the on state to less than a predetermined number. 11. The apparatus according to any one of claims 1 to 7, wherein when a predetermined number or more of solenoid valves should be turned on at the same time, the solenoid valves are turned off in descending order of operating rate. A showcase cooling device comprising: an operating number limiting unit for keeping the number of solenoid valves that are in the ON state at the same time and less than a predetermined number at the same time.