JPH0820127B2 - Refrigeration system operation controller - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operation control device for a refrigerating device that controls the start / stop of a compressor based on a predetermined differential width, and particularly a measure for improving control accuracy. Regarding

(Prior Art) Conventionally, as disclosed, for example, in Japanese Utility Model Laid-Open No. 63-78871, a first differential having a temperature region centered on a set temperature of a thermostat and a width included in the first differential. In the operation control device of the refrigerating apparatus, in which the start and stop of the compressor are controlled by the upper and lower limits of each differential, the first differential is set immediately after the start of operation.
While starting and stopping the compressor according to the differential,
When it is judged that the predetermined time has passed without causing the oil to rise in the compressor or the start-up lock, etc., it is changed to the second differential, so that the set temperature is rapidly converged at the beginning of operation and the set temperature is set after the conditions are stabilized. It is a known technique to maintain the temperature in the vicinity.

(Problems to be Solved by the Invention) However, when the compressor is started and stopped according to the wide first differential immediately after the start of operation as in the above-described conventional one, operation is performed with a wider differential width than necessary. As a result, the change range of the temperature to be controlled becomes wider, resulting in a problem that it is difficult to realize highly accurate control even if the load is stable and the number of times of starting and stopping the compressor is reduced. .

The present invention has been made in view of such a point, and an object thereof is to control on / off of a compressor based on a narrow differential width immediately after the start of operation,
It is to make the controlled temperature accurately converge to the set temperature.

(Means for Solving the Problem) In order to achieve the above-mentioned object, the means taken by the invention according to claim 1 is provided with a refrigerating circuit as shown in FIG. Intended for refrigeration equipment that is designed to be maintained.

Then, a thermostat (72) that detects the temperature to be controlled and outputs a signal to turn on / off the compressor of the refrigeration circuit according to the temperature to be controlled, and the thermostat (72) outputs an on signal when the operation is started. Differential setting means (10) for setting the differential width between the upper temperature to be turned on and the lower temperature to output the off signal to a predetermined initial temperature width.
1) and a counting means (71) for counting the start / stop frequency of the compressor after the operation is started.

Further, when the frequency of starting and stopping the compressor becomes equal to or higher than the first set frequency when a predetermined time has elapsed after the start of operation by receiving the output of the counting means (71), the differential width is changed to the second temperature width wider than the initial temperature width. The first changing means (102a) for changing and the output of the counting means (71), and the first changing means (102a)
When the start / stop frequency of the compressor is equal to or more than the first set frequency after a certain time has elapsed after the start of the operation based on the second temperature range changed in step 3, the differential width is changed to the third temperature range wider than the second temperature range. Second changing means (102b) for changing is provided.

In addition, when the output of the counting means (71) is received and a certain time has elapsed after the start of operation based on the second temperature range changed by the first changing means (102a), the frequency of starting and stopping the compressor is the first
When the frequency is equal to or lower than the second setting frequency which is smaller than the setting frequency, the output of the first returning means (103a) for returning the differential width to the initial temperature width and the counting means (71) is received,
When a certain time has elapsed after the start of operation based on the third temperature range changed by the second changing means (102b), the compressor start / stop frequency is less than the third set frequency and is less than or equal to the third set frequency. A second return means (103b) is provided for returning the differential width to the second temperature width when the fourth setting frequency is smaller than the third setting frequency, and to the first temperature width when the fourth setting frequency is less than the fourth setting frequency. Has been.

(Operation) With the above configuration, in the invention according to claim 1, the differential setting means (10
Since the differential width of the thermostat (72) is set to a narrow initial temperature range by 1), the compressor turns on and off between the upper limit value and the lower limit value of this initial differential width, and the control target temperature is It changes within the temperature range.

In addition, when the start / stop frequency of the compressor (start / stop frequency per unit time) increases during operation at this initial temperature range, the differential width is changed to a wider range, increasing the start / stop frequency of the compressor. Problems such as oil going up are avoided.

That is, as the differential width, the second temperature width having a width between the initial temperature width and the third temperature width is set, and even if the number of times of starting and stopping the compressor exceeds the first setting frequency,
The second changing means is first changed to the second temperature range by the first changing means (102a) without immediately changing to the wider third temperature range, and when the frequency of starting and stopping the compressor is not reduced yet. By (102b), the differential width is changed to the third temperature width.

Therefore, the control accuracy is improved without causing deterioration of the control accuracy of the temperature to be controlled due to the continuous operation for a long time with a wide differential width.

Then, after that, when the operating condition becomes stable and the frequency of starting and stopping the compressor decreases, the first and second restoring means (103a),
(103b) allows the differential width to return to the initial temperature range, so that the oil pressure of the compressor is avoided while maintaining control accuracy as much as possible, and the differential width is narrowed quickly when the operating condition is stable. It will be changed and it will respond promptly to the stabilization of operating conditions.

(Embodiment) An embodiment of the present invention will be described below with reference to the drawings starting from FIG.

FIG. 2 shows the configuration of the control circuit of the refrigerating apparatus according to the embodiment of the present invention, and (RB) is a relay board for controlling the operation of each device arranged in the outdoor unit (not shown) of the refrigerating apparatus. , (EC ₁ ) is a printed circuit board of a remote control device (not shown) for remotely controlling the relay board (RB), (2a)
Is an indoor control unit that is connected to the relay board (RB) of the outdoor unit and controls the operation of each device in the indoor unit (not shown).

The relay board (RB) is connected to a single-phase component of a three-phase AC power supply (V), and the relay board (RB) has a compressor motor (MC) as an external device and the compressor motor ( MC) electromagnetic contactor (52C), liquid injection valve (20R1), four-way switching valve (20S) for switching the refrigeration cycle forward and reverse, and hot gas bypass valve connected in parallel with the four-way switching valve Electromagnetic relay (20SX), outdoor fan motor (MF1), and pressure switch (6
3H), a temperature controller (23A) for the outside air temperature, and an electromagnetic relay (26D) that is linked to the switching of the temperature controller (23A) to the high temperature side.
X), the crankcase heater (CH), and the temperature controller (23) for the crankcase heater (CH) that opens when the temperature is high.
AH), and a compressor temperature protection switch (49C), an overcurrent relay (51C), and a reverse phase protection relay (47) connected in series to a protection electromagnetic relay (30FX) for the compressor motor (MC) described later. ) And the hot gas bypass valve (20R2) are connected.

Inside the relay board (RB), the electromagnetic relay (52F1) for the outdoor fan motor (MF1), the electromagnetic relay (52F2) for the internal fan motors (MF2) to (MF4), and the compressor motor (MC ) And an electromagnetic relay (30FX) for protection are arranged, and the contacts of each of the electromagnetic relays are arranged.

Further, the internal control unit (2a) is connected to internal fan motors (MF2) to (MF4) and temperature switches (26D1) and (26D2) for ending defrosting.

On the other hand, on the printed circuit board (EC ₁ ) of the remote control device, the alarm output electromagnetic relay (RY1) and the compressor motor (M
C) Starting electromagnetic relay (RY2), outdoor fan (MF1) Starting electromagnetic relay (RY4), internal fan (MF2) ~ (MF
4) Starting electromagnetic relay (RY5), four-way switching valve (20S) switching electromagnetic relay (RY6), CPU (70) that is the central processing unit that controls these operations, and start / stop of the compressor A counter (71) as counting means for counting the frequency is arranged. Further, a remote control box (EC ₂ ) which is an operation unit is connected to the printed circuit board (EC ₁ ) of the above remote control device so as to be able to send and receive signals, and the remote control box (EC ₂ ) allows setting of temperature conditions and the like. Is supposed to do.

A thermostat (72) is arranged in the remote control box (EC ₂ ), and a printed circuit board (EC ₁ ) of the remote control device has a thermistor (temperature detection part of the thermostat (72) for detecting the temperature inside the refrigerator. The thermostat (72) is connected from the thermistor (Th) based on a predetermined set temperature Ts set by the setting button of the remote control box (EC ₂ ). The ON / OFF switching signal of the compressor is output according to the temperature signal of.

That is, as shown in FIG. 3, for example, when the differential width is 2 ° C., the temperature Ta in the refrigerator decreases by operating, and when it reaches (Ts) ° C., an off signal of the compressor is output, and the compressor is output. Temperature Ta rises during the stop of (Ts + 2) ℃
When it reaches, the compressor ON signal is output again. And
As shown in FIG. 4, the internal temperature Ta changes cyclically between the set temperature Ts ° C. and the differential upper limit value (Ts + 2) ° C. (see FIG. 4A), and the compressor changes accordingly. The start and stop according to the above is repeated (see (b) in the figure).

Further, the differential width of the thermostat (72) is variable, and as shown in FIG. 5, the narrowest 2 ° C., the widest 4 ° C., and the intermediate width of both 3 ° C.
3 types of differential widths can be set, and the switching characteristics of the thermostat (72) are changed among the characteristics shown in the same figure according to the change of the differential widths.

In the printed circuit board (EC ₁ ) of the remote control device, (X1) is the remote input terminal, (X2) is the protective device input terminal, (X3) is the defrost end input terminal, and (Tr) is for connecting external devices. Is a transformer. Further, in the printed circuit board (RB) of the outdoor control unit, (X4) is an anti-phase protection input terminal.

Next, the start / stop control of the compressor by the CPU (70) will be described based on the flowchart of FIG. 6. In step S ₁ , the internal temperature Ta is set as the setting condition immediately after the start of operation.
When the internal temperature Ta is lower than the set temperature Ts (lower limit value), the compressor is turned off, and when the internal temperature Ta is higher than the upper limit value (Ts + 2) ° C, the compressor is turned on, that is, the differential width is set to the initial temperature. Set a narrow temperature range of 2 ° C.
Then, 1 hour (predetermined time) after the start of operation of the compressor in this condition when the elapsed, the process proceeds to step S _2, start-stop frequency per unit of the compressor time (start-stop frequency) first set Frequency (7 times / hour) or more is determined, and if the frequency is lower than the first set frequency, the process returns to step S ₁ to continue the operation as it is, but the start / stop frequency of the compressor is the first set frequency (7 times / hour). time)
If more, the process proceeds to step S ₃ determines that the operation state is unstable, and sets the differential width slightly larger second temperature range 3 ° C. than the initial temperature range.

Next, when 1 hour has passed after the start of the operation based on the second temperature range of 3 ° C., the process proceeds to step S _4, and whether the compressor start / stop frequency is the first set frequency (7 times / hour) or more. whether, that control it is determined whether or not reached a stable state, the smaller start-stop frequency than the first set frequency (7 times / hour), the process proceeds to step S _5, even more the first set frequency Is smaller than the second setting frequency (5 times / hour) or less. If the start / stop frequency of the compressor is less than or equal to the second set frequency (5 times / hour), it is determined that the compressor is in a stable state, and the above step S ₁
Returning to above, while the operation based on the above-mentioned initial temperature range of 2 ° C is performed, if the start / stop frequency of the compressor is higher than the second set frequency (5 times / hour), it is determined that the stable state has not yet been reached. Returning to step S ₃ , the operation based on the second temperature range of 3 ° C. is continued.

Furthermore, in the judgment at the step S _4, when start-stop frequency of the compressor is equal to or larger than the first set frequency (7 times / hour), it is determined that have become more unstable state, the flow proceeds to step S _6,
The differential width of the third temperature narrower than the second temperature width
Change to temperature range (4 ° C). Then, when one hour has elapsed after the start of the operation based on the third temperature range (4 ° C.), in step S ₇ , the frequency of starting and stopping the compressor is set to the first set frequency (7
It is determined whether or not the third set frequency (6 times / hour) or more, which is smaller than the second set frequency and is larger than the second set frequency, and the start / stop frequency is the third set frequency (6 times / hour) or more. if, it is determined that the operation state is not stable enough, the process returns to step S _6, while continuing the operation based on the third temperature range 4 ° C., start-stop frequency of the compressor is the third set frequency (6 times / is smaller than the time), further proceeds to step S _8, start-stop frequency of the compressor whether the third fourth predetermined frequency (3 times / time less than the set frequency (6 times / h)) less Determine.

If the start / stop frequency of the compressor is higher than the fourth set temperature (3 times / hour), it is determined that the stable state has not yet been reached, and the process returns to step S ₃ and the second temperature range is set to 3 ° C. On the other hand, if the frequency of starting and stopping the compressor is less than or equal to the fourth set frequency (3 times / hour), it is determined that the stable state has been reached, and the process returns to step S ₁ and the initial temperature range is set to 2 ° C. Return to normal operation.

In the above flow, the differential setting for setting the differential width between the upper temperature at which the thermostat outputs the ON signal and the lower temperature at which the thermostat outputs the OFF signal to the predetermined initial temperature width of 2 ° C. at the start of operation by the control of step S ₁ Means (101) are configured.

Further, the control in step S _3, the counter (counting means) (71) outputs the received of, start-stop frequency of the compressor when the predetermined elapsed after the start operation time first set frequency (7 times / hour)
In the above case, the first changing means (102) for changing the differential width to the second temperature width 3 ° C. wider than the initial temperature width 2 ° C.
a) is configured.

Further, the control of the step S _6, the output of the counter (counting means) (71) receives, when the elapsed second temperature range 3 ° C. to based operation start after a predetermined time has been changed by the first changing means (102a) When the start / stop frequency of the compressor is equal to or higher than the first set frequency (7 times / hour), the differential width is changed to the third temperature width 4 ° C, which is wider than the second temperature width 3 ° C.
Change means (102b) is configured.

On the other hand, by the control of shifting from step S ₅ to S ₁ , the start / stop frequency of the compressor is changed when a certain time has elapsed after the start of the operation based on the second temperature range 3 ° C. changed by the first changing means (102a). Second less than the first set frequency (7 times / hour)
A first restoring means (103a) is configured to restore the differential width to the above-mentioned initial temperature width of 2 ° C. when the frequency is less than the set frequency (5 times / hour).

Further, the control proceeds from step S ₈ to S ₃ or S _1, the compressor when passed the second changing means (102b) a third temperature range 4 ° C. to based operation start after a predetermined time has been changed by calling The stop frequency is less than or equal to a third set frequency (6 times / hour) that is smaller than the first set frequency (7 times / hour), and the third
If the fourth setting frequency (3 times / hour) is smaller than the setting frequency (6 times / hour) or more, the differential width is set to the second temperature range of 3 ° C. and the fourth setting frequency (3 times / hour) or less. If there is, a second returning means (103b) for returning to the first temperature range of 2 ° C. is configured.

Therefore, in the above embodiment, FIGS. 7 (a) and 7 (b)
As shown in (a) of the figure, the temperature Ta in the refrigerator changes with time, and (b) of the figure shows time change of the compressor on / off. As shown in FIG.
Since the differential width of the thermostat (72) is set to 2 ° C. (the switching characteristic of FIG. 5) where the differential width of the thermostat (72) is set by 1), the internal temperature Ta changes within this initial temperature range of 2 ° C. 7 (a) area). That is, as in the above-mentioned conventional case, a wide differential width is initially set to start and stop the compressor, and when the refrigerating operation reaches a predetermined stable condition, the differential width is changed to a narrow value. However, it takes time for the refrigeration operation to stabilize, and even though the load is stable, the operation is often continued with a wide differential width, which may deteriorate the control accuracy of the internal temperature Ta. In the present invention, the differential width is initially set to a narrow initial temperature width of 2 ° C.,
Since the compressor is started and stopped based on this initial temperature width of 2 ° C., the control accuracy of the internal temperature Ta can be improved.

When the start / stop frequency of the compressor (the start / stop frequency per unit time) increases during the operation at the initial temperature range of 2 ° C. (for example, the first set frequency (7 times / hour) in the first embodiment). , The differential value is changed to a second temperature range 3 ° C. (or a third temperature range 4 ° C.) wider than the initial temperature range 2 ° C. (that is, the switching characteristic of FIG. 5 or) (FIG. 7 (a)). Therefore, the number of times of starting and stopping the compressor is reduced (the area in FIG. 7 (b) or), and the compressor can be operated without causing trouble such as oil rising.

Further, as shown in FIGS. 8 (a) and 8 (b), after the differential width is changed, while the refrigerating operation is performed to start / stop the compressor based on, for example, the third temperature width 4 ° C. (FIG. 8). In the region (a)), when the number of times of starting and stopping the compressor is reduced again, for example, when it is less than the second set frequency (5 times / hour) in the first embodiment, the differential width becomes the initial temperature width of 2 ° C. The differential width is rapidly changed when the operating condition becomes stable, while preventing the trouble such as the oil rising of the compressor. It is possible to quickly respond to the stabilization of the state, so
The effect of improving the control accuracy can be more remarkably exhibited.

In particular, as the differential width, a second temperature width of 4 ° C. is set between an initial temperature width of 2 ° C. and a third temperature width of 3 ° C., and the compressor start / stop count is set to the first set frequency (7 times / hour). ) Is not immediately changed to a wide third temperature range of 4 ° C, but the first change means (102a) is used to temporarily change the second temperature range of 3 ° C, and then the frequency of starting and stopping the compressor is still reduced. If not, the differential width is changed to the third temperature width of 4 ° C. by the second changing means (102b), and thereafter, when the operating condition becomes stable and the start / stop frequency of the compressor decreases, the first and second returning means respectively. Since the differential width is returned to the initial temperature width of 2 ° C. by (103a) and (103b), it is possible to avoid the oil rising of the compressor while maintaining the control accuracy as much as possible. The effect can be even more pronounced .

Next, a second embodiment will be described. FIG. 9 shows switching characteristics of the thermostat according to the second embodiment. In this embodiment, the thermostat is a so-called two-step thermostat, and the compressor is controlled by the unloader mechanism in three stages of full load, unload and off. It is something. That is, when the internal temperature Ta decreases to (Ts + 0.5) ° C, it is unloaded, and when the internal temperature Ta further decreases to the set temperature Ts, the thermostat is turned off. When Ta rises to reach (Ts + 1.0) ° C, it is unloaded, and the inside temperature Ta rises (Ts + 1.
5) It is set to switch to full load again when the temperature reaches ℃.

Then, when the internal temperature Ta decreases, the internal temperature Ta becomes (Ts + 0.
5) The temperature changes between ℃ and (Ts + 1.5) ℃ (see (a) in the same figure), the compressor is always on (see (b) in the same figure), and the unloader repeatedly turns on and off (see the same figure). (See (c)). On the other hand, when the internal temperature Ta rises, the internal temperature Ta changes between the set temperature Ts and (Ts + 1.0) ° C. as shown in FIGS. (See (a)), the compressor is repeatedly turned on and off (see (b) of the same figure), and the unloader is always kept on (see (c) of the same figure).

Also in this embodiment, the differential width between the unload and the thermo-off can be changed between 1.0 ° C, 1.5 ° C and 2.0 ° C, and accordingly, the switching characteristic between the unload and the thermo-off of the thermostat can be changed. Each is changed to the three types shown in FIGS. 12A and 12B, and the switching value between full load and unload is moved in parallel to the high temperature side accordingly (see FIGS. 12A to 12C).
That is, as shown in FIGS. 13 (a) to 13 (c) ((a) in FIG. 13 is a time variation of the inside temperature Ta, (b) is a time variation of on / off of the compressor, and (b) in FIG. (c) shows changes with time of the unloader), and at the beginning of the operation, the differential setting means (101) sets the differential width between the unload and the thermo-off to the initial temperature width of 1 ° C. ((a) to (c) in the figure). )), When the frequency of starting and stopping the compressor increases, the differential width is changed to the second temperature range of 1.5 ° C. by the first and second changing means (102a) and (102b) ((a) to (c) in the figure). )) And the third temperature width of 2.0 ° C. (areas (a) to (c) in the figure). The operation of the first and second returning means (103a), (103b) is also the same as in the first embodiment.

Therefore, also in the second embodiment, the same effect as in the first embodiment can be exhibited.

Although not described, the same applies to a case in which a plurality of compressors are provided and the operating capacity of the compressor is switched in multiple stages by turning on / off each of them.

(Effect of the invention) As described above, according to the invention of claim 1,
A thermostat that detects the temperature inside the refrigerator and outputs a signal that switches the compressor on and off is placed as the operation control device of the refrigeration system.At the beginning of the refrigeration system operation, the differential width of the thermostat is set to a narrow initial temperature range. On the other hand, since the differential width is changed to be wider while the frequency of starting and stopping the compressor increases during operation, the temperature inside the refrigerator changes from the beginning of operation without deteriorating the control accuracy due to the wide differential width. The range can be converged small, and thus the control accuracy of the internal cold storage temperature can be improved.

Further, when the frequency of starting and stopping the compressor decreases after the differential width is changed, the differential width is made to recover toward the initial temperature width, so while preventing problems such as oil rising in the compressor, control of Highly accurate control can be performed corresponding to stabilization.

In particular, the second and third temperature ranges are provided for the initial temperature range,
The differential width is gradually widened according to the increase in the start / stop frequency of the compressor, while the second temperature range and the initial temperature range are gradually restored according to the stabilization of the operating state. As much as possible, it is possible to perform highly accurate control based on a narrow differential width while avoiding problems such as oil rising in the compressor, and thus it is possible to achieve the above effects more remarkably.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of the present invention. 2 to 8 show a first embodiment of the present invention, FIG. 2 is an electric circuit diagram showing a configuration of a control circuit, FIG. 3 is a characteristic diagram showing a switching characteristic of a thermostat, and FIG. 4 (a). ) And (b) are time charts showing changes in the temperature inside the refrigerator and changes in the start and stop of the compressor according to the switching characteristics of the thermostat, and FIG. 5 is an explanation showing changes in the switching characteristics due to changes in the differential width of the thermostat. 6 and 6 are flow charts showing the control contents of the CPU, and FIGS. 7 (a) and 7 (b) show the procedure for changing the differential width. The change in the internal temperature with time and the turning on of the compressor FIGS. 8 (a) and 8 (b) show a time chart showing an off change, and FIG. 8 (a) and (b) show a procedure for restoring the differential width. Over preparative view, Figure 9 below illustrates a second embodiment, FIG. 9 is a characteristic diagram showing the Switching Characteristics of two-step thermostat, FIG. 10 (a) ~ (c) and FIG. 11 (a) ~
(C) is a time chart showing changes in the internal temperature with respect to time, changes in the compressor on / off, and changes in the unloader on / off, and Fig. 12 shows changes in the differential width of the 2-step thermostat. FIGS. 13 (a) to 13 (c) are explanatory views showing changes in the switching characteristics, showing a procedure for changing the differential width. In each case, changes in the internal temperature with time, changes in the compressor on / off, and changes in the unloader are shown in order. It is a time chart figure which shows ON / OFF change. 71 ... Counter (counting means) 72 ... Thermostat 101 ... Differential setting means 102a ... First changing means 102b ... Second changing means 103a ... First returning means 103b ... Second returning means

Claims (1)

[Claims] Claim: What is claimed is: 1. A refrigerating apparatus comprising a refrigeration circuit for maintaining a controlled object at a predetermined low temperature state, detecting a controlled object temperature, and turning on / off a compressor of the refrigerated circuit according to the controlled object temperature. Set the differential width between the thermostat (72) that outputs a signal to cause the thermostat (72) to output an ON signal and the lower temperature that outputs an OFF signal to a predetermined initial temperature width when the thermostat (72) starts operation. Differential setting means (101) and counting means (7) for counting the start / stop frequency of the compressor after the start of operation.
1) and receiving the output of the counting means (71), when the start / stop frequency of the compressor becomes equal to or higher than the first set frequency after a lapse of a predetermined time after the start of operation, the differential width is made wider than the initial temperature width.
The first changing means (102a) for changing the temperature range and the output of the counting means (71) receive the first changing means (102).
When the start / stop frequency of the compressor is equal to or more than the first set frequency after a certain time has elapsed after the start of operation based on the second temperature range changed in a), the differential width is set to the third temperature wider than the second temperature range. Second changing means (102b) for changing the width
And receiving the output of the counting means (71), the first changing means (102
When the start / stop frequency of the compressor is equal to or less than the second preset frequency, which is smaller than the first preset frequency when a certain time has elapsed after the start of operation based on the second preset temperature range changed in a), the differential width is set to the initial temperature span. Receiving the output of the counting means (71) and the second changing means (102a)
When a certain time has elapsed after the start of operation based on the third temperature range changed in b), the start / stop frequency of the compressor is less than or equal to the third setting frequency that is less than the second setting frequency, and more than the third setting frequency. And a second return means (103b) for returning the differential width to the second temperature range when the frequency is smaller than the fourth setting frequency and to the first temperature range when the frequency is less than the fourth setting frequency. Operation control device for refrigeration equipment.