JP5972018B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner, and more particularly to a unit control for avoiding a short cycle when operating a plurality of air heat source refrigeration apparatuses.

When a plurality of air conditioners (called outdoor units) are installed, a short cycle (also called a short circuit) may occur between adjacent outdoor units. The short cycle is a phenomenon in which the outdoor unit itself sucks the air discharged by the outdoor unit again, or another adjacent outdoor unit sucks the air, causing the temperature of the heat exchanger to rise, This may cause performance degradation.
Conventionally, a technique for detecting such a short cycle has been proposed (see, for example, Patent Document 1). This is because the temperature difference is obtained from the outside air temperature and the outdoor unit suction temperature, and the difference value obtained by subtracting the minimum value of a plurality of temperature differences before the latest time point from the temperature difference at the latest time point and a predetermined threshold. The short cycle is detected by comparing the value. However, the technique of Patent Document 1 is a technique for detecting a short cycle when operating a plurality of outdoor units, and avoids the short cycle in consideration of the installation environment of the outdoor unit and the natural environment such as temperature and wind speed. It is not related to the number control of such air conditioners. In addition, prior art documents relating to the number control that avoids such a short cycle could not be found.

JP 2002-349926 A

  By the way, in the prior art, the control of multiple air heat source refrigerators is controlled so that the accumulated operation time of all outdoor units is equal, and the local unit installation environment, temperature, wind speed, etc. Because the natural environment was not taken into account, a short cycle occurred due to the influence of wind and the operation efficiency of the outdoor unit was reduced.

  The present invention was made to solve the above problems, and when controlling the number of a plurality of air conditioners, considering the installation environment of the air conditioner and the natural environment such as temperature and wind speed, It is to realize unit control that suppresses the decrease in operating efficiency of the air conditioner due to a short cycle.

An air conditioner according to the present invention includes a plurality of outdoor units, a unit control device that performs control to avoid a short cycle between adjacent outdoor units, and an anemometer that measures a wind direction and a wind speed at a place where the outdoor unit is installed. And the number control device, the installation environment information of the outdoor unit, the installation information in which the installation position and unit number of the outdoor unit are identified, the natural environment information of the installation location of the outdoor unit, Wind information of the wind direction and wind speed at the installation location of the outdoor unit obtained by measurement with the anemometer, and operation accumulated time information obtained by integrating individual operation times of the outdoor unit, and the installation environment information , the natural environment information, based on the mounting information, the cumulative operation time information and wind information, to suppress the reduction in the operating efficiency due to a short cycle It selects the first driving block including a plurality of outdoor units as, and is what determines the operating sequence of the outdoor units in the operation block.

  In the air conditioner according to the present invention, the unit control device determines the operation order of the outdoor units so as to suppress the reduction of the operation efficiency due to the short cycle based on the installation environment information and the natural environment information. The occurrence of short cycles due to changes in the natural environment at the installation location of the outdoor unit can be reduced, thereby improving the operating efficiency of the entire outdoor unit.

It is a system configuration figure of the air harmony device concerning Embodiment 1 of the present invention. It is a system configuration | structure figure of the air conditioning apparatus which concerns on Embodiment 2 of this invention. It is a system block diagram of the air conditioning apparatus which concerns on Embodiment 3 of this invention. It is a system block diagram of the air conditioning apparatus which concerns on Embodiment 4 of this invention. It is a flowchart of the number control of the air conditioning apparatus which concerns on Embodiment 5 of this invention.

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

Embodiment 1 FIG.
FIG. 1 is a system configuration diagram of an air-conditioning apparatus according to Embodiment 1 of the present invention.
In FIG. 1 outdoor unit 11 and no. It is assumed that the two outdoor units 12 are installed in an appropriate place. What controls the operation of these two outdoor units 11 and 12 is a control controller 10, that is, a unit control device. The two outdoor units 11 and 12 and the number control device 10 are connected in parallel by cables 20. An anemometer 30 for measuring the wind direction and the wind speed at the installation location of the outdoor units 11 and 12 is installed on the unit control device 10, for example. As long as the anemometer 30 can accurately measure the wind direction and the wind speed at the installation location of the outdoor units 11 and 12, the installation position of the anemometer 30 is not particularly limited.

The outdoor units 11 and 12 include a compressor, a four-way valve and an expansion valve (both not shown) installed in the machine room 21, an air heat exchanger 22 that performs heat exchange between air and a refrigerant, and air heat exchange. A blower 23 that blows outside air to the compressor 22, a temperature sensor 24 that measures the suction temperature that is the temperature of the outside air that flows into the air heat exchanger 22, and various sensors and devices for controlling the compressor and the expansion valve Piping and wiring for connecting the cable. Moreover, the outdoor units 11 and 12 are comprised from the unit whose cooling capacity is a capacity unit equivalent to 60 horsepower (180 kW), for example.
Moreover, the outdoor units 11 and 12 and the indoor unit on the use side are connected so that the refrigerant circulates through a pipe. The indoor unit includes, for example, a water heat exchanger that performs heat exchange between cold / hot water and a refrigerant, an expansion valve, and the like. The refrigerant circulates at least through the compressor, the air heat exchanger (air-cooled condenser) 22, the expansion valve, the water heat exchanger, the air heat exchanger (evaporator), or the like, thereby forming a refrigeration circuit. Yes.

The number control device 10 stores and stores in the storage device installation environment information such as the installation positions and intervals of the outdoor units 11 and 12 and natural environment information such as wind direction, wind speed, and temperature at the installation locations of the outdoor units 11 and 12. doing. The installation environment information of the outdoor units 11 and 12 is mainly installation information in which the installation positions and unit numbers of the outdoor units 11 and 12 are identified. The storage device stores operation integration time information obtained by integrating the individual operation times (continuous or intermittent) of the outdoor units 11 and 12.
Data measured by the anemometer 30 is used as the wind information related to the wind direction and wind speed at the installation locations of the outdoor units 11 and 12.

In the air conditioner according to the first embodiment, the number control device 10 is based on the installation environment information of the outdoor units 11 and 12 and the natural environment information of the installation locations of the outdoor units 11 and 12, that is, the installation information described above, Based on the operation integration time information and wind information, the outdoor unit 11 or 12 to be operated first is determined so as to suppress the reduction in operation efficiency due to the short cycle.
Therefore, a short cycle between the adjacent outdoor units 11 and 12 can be avoided, and thereby reduction in operating efficiency can be suppressed.

Embodiment 2. FIG.
FIG. 2 shows a system configuration diagram of an air-conditioning apparatus according to Embodiment 2 of the present invention. The figure shows an air conditioner system in which outdoor units 11 to 19 of No. 1 to No. 9 having a 3 × 3 arrangement are installed as an example.
In the second embodiment, the number of units is controlled using the measurement data of the anemometer 30. That is, the anemometer 30 measures the wind direction and the wind speed at the site (places where the outdoor units 11 to 19 are installed), and inputs the wind information to the number control device 10 as wind information.

  In the case of the second embodiment, the operation order of the outdoor units is such that the unit group that is in a horizontal row with respect to the wind direction is one operation block, and the operation is performed from the operation block on the windward side. In this case, the operation order in the operation block is the order from the operation integration time information to the operation integration time in ascending order. By setting it as such an operation | movement order, the average of the operation time of the outdoor unit in the said operation block can be aimed at. In addition, if the capacity of one driving block is insufficient, the second driving block is started, but the second driving block is selected not to be adjacent to the first driving block. .

For example, in FIG. 2, when the wind direction is “wind direction 1”, the first operation block to be operated is the outdoor unit (11, 12, 13) on the windward side. And the operation | movement order in an outdoor unit (11,12,13) shall be the order with little operation | movement integration time. When the capacity increases, the non-adjacent block is set as the second operation block. In this case, the outdoor unit (17, 18, 19) is set as the second operation block. The operation order of the outdoor units (17, 18, 19) in the second operation block is also the order in which the operation integration time is short.
Further, the outdoor units (14, 15, 16) in the central row are operated when the load side capacity becomes large (when unit operation of 6 or more units is required). Even in this case, the operation order in the outdoor units (14, 15, 16) in the center row is the order in which the operation integration time is short as in the first and second operation blocks.

  For example, in FIG. 2, when the wind direction is “wind direction 3”, the first operation block to be operated is the windward outdoor unit (11, 14, 17), and the operation sequence in this operation block is The order of the accumulated operation time is ascending. Similarly, the operation block to be operated second is an outdoor unit (13, 16, 19) of a block that is not adjacent to the first operation block. It becomes.

  Here, the reason for starting operation from the outdoor unit on the windward side is as follows. For example, in FIG. 2, when the operation is started from the leeward side, when “wind direction 2” is generated, the operation is started from the block of the outdoor unit (11, 12, 13). There may be a wall (obstacle), which may cause a short cycle. Therefore, the operation is started from the outdoor unit on the windward side.

  As described above, according to the second embodiment, when the capacity is low, since the windward operation block is operated first, the exhaust heat discharged by the downstream outdoor unit from the upstream outdoor unit is reduced. It is possible to suppress a decrease in operating efficiency due to the short cycle due to the suction. In addition, even when the capacity increases, the outdoor unit does not operate in the adjacent operation block, so that it is possible to expect the effect of suppressing the decrease in operation efficiency.

Embodiment 3 FIG.
FIG. 3 shows a system configuration diagram of an air-conditioning apparatus according to Embodiment 3 of the present invention.
In the third embodiment, the number of units is controlled using the measurement data of the temperature sensor 24 attached to the air heat exchanger 22. That is, the temperature sensor 24 attached to the air heat exchanger 22 measures the outside air temperature flowing into the air heat exchanger 22 (hereinafter referred to as suction temperature). The suction temperature data is input to the number control device 10 and stored in the storage device. And the number control apparatus 10 determines the driving | operation order of the outdoor units 11-14 based on this suction temperature data and the above-mentioned installation information. For example, in the cooling operation, the suction temperature obtained by the temperature sensor 24 is in ascending order, and in the heating operation, the suction temperature is in the descending order. In the cooling operation, the operation efficiency is improved by balancing the condensation temperature of the air heat exchanger of the outdoor unit, and in the heating operation, the balance of the evaporation temperature of the air heat exchanger of the outdoor unit. It is for improving.

  According to the third embodiment, the number control device 10 determines the outdoor units 11 to 11 in order of increasing or decreasing suction temperature based on the installation information of the outdoor units 11 to 14 and the suction temperature information of the air heat exchanger 22. Since the operation order of 14 is determined, it is effective especially when the number is small.

Embodiment 4 FIG.
FIG. 4 shows a system configuration diagram of an air-conditioning apparatus according to Embodiment 4 of the present invention.
In the fourth embodiment, the operation order of the outdoor units 11 to 19 is determined based only on the installation information of the outdoor units 11 to 19 in the field so that the number control device 10 suppresses the reduction of the operation efficiency due to the short cycle. is there.

Here, the operation sequence by installation is defined as follows. Of the outdoor units each having four side surfaces, there are few side surfaces adjacent to each other, or there are many side surfaces where there are no air path obstructions (for example, walls or buildings) within a certain distance from the side surface of the outdoor unit. The outdoor unit will be operated with priority.
For example, in the case of FIG. 4, the outdoor units 11 to 19 are installed in a 3 × 3 arrangement. Assuming that there are no obstacles on the outer periphery of the outdoor units 11 to 19 in this arrangement, the outdoor units (19, 17, 14, 11) have few side surfaces where the outdoor units are adjacent to each other. (19, 17, 13, 11) is set as the first operation block, and the operation is preferentially performed from this operation block (the operation order is the order in which the operation integration time is short).
Further, in the outdoor units (16, 12, 14, 18), there are three side surfaces where the outdoor units are adjacent to each other, and there are few next to the two surfaces, so these outdoor units (16, 12, 14, 18). Is the second driving block. The operation order in the second operation block is the order in which the operation integration time is short like the first operation block.
Since the remaining outdoor units 15 are adjacent to all the side surfaces, the outdoor units 15 are operated last.

  According to the fourth embodiment, since the operation order of the outdoor units 11 to 19 is determined only from the installation information of the outdoor units 11 to 19 according to the local installation environment, the anemometer 30 or the like as in the first to third embodiments. Since the temperature sensor 24 is not used, a reduction in operating efficiency due to a short cycle can be suppressed at a low cost.

Embodiment 5 FIG.
FIG. 5 shows a flowchart for controlling the number of air-conditioning apparatuses according to Embodiment 5 of the present invention. The figure shows the flow of unit control described in the first to fourth embodiments.

  First, in STEP 1, the wind speed at the place where the outdoor unit is installed is measured by the anemometer 30. At this time, if the wind speed is equal to or lower than the predetermined wind speed, it is considered that the short cycle is less affected by the wind. Further, if the wind speed is equal to or higher than the predetermined wind speed, it is considered that the influence of the short cycle due to the wind is large. Therefore, based on the first and second embodiments, the operation order of the outdoor units is determined and the operation is started. Then, it moves to STEP2.

  In STEP 2, the maximum value and the minimum value of the suction temperature (air heat exchanger temperature) are measured by the temperature sensor 24 mounted on the air heat exchanger 22 of each outdoor unit. At this time, if the temperature difference between the maximum value and the minimum value is within a predetermined temperature difference, the number control is performed based on the first and second embodiments, and the operation is started in the order determined from the wind direction. If the temperature difference is equal to or larger than the predetermined temperature difference, the number control is performed based on the first and third embodiments, and the operation is started in the order of low or high suction temperature (air heat exchanger temperature).

  Note that the conditions for NO in STEP 2 are when the wind speed is above a certain level and when there is a temperature difference between the maximum value and the minimum value of the air heat exchanger temperature of each outdoor unit above a certain level. This is because the high temperature range and the low temperature range can be made extremely depending on the installation environment (the temperature sent from the blower accumulates in one place depending on the installation environment), so the maximum value of the air heat exchanger temperature We are going to look at the minimum value.

  If NO in STEP 1, that is, if it is considered that the influence of the short cycle due to the wind is small, the process proceeds to STEP 3. And in STEP3, the maximum value and minimum value of the operation integration time of each outdoor unit are measured. At this time, if the time difference between the maximum value and the minimum value of the operation integration time is within a predetermined time difference, the process proceeds to STEP4. Moreover, if the time difference between the maximum value and the minimum value of the operation integration time is not within the predetermined time difference, the operation is started in ascending order of the operation integration time of the outdoor unit. This is set as a backup position in order to prevent variations in the accumulated operation time of each outdoor unit. This setting is to prevent that only one outdoor unit is always operated and only one outdoor unit is always stopped.

  In STEP 4, pattern 1 or pattern 2 is selected based on a predetermined selection criterion. Patterns 1 and 2 can be changed by the customer (installation environment). For example, when the customer's installation environment is complicated (when it is not the 3 × 3 arrangement shown in FIG. 2), the number control by “determining” as in pattern 2 may be good, so that it can be selected.

  When the pattern 1 is selected, the pattern 1 starts the operation in the order of low or high air heat exchanger temperature of each outdoor unit. For example, in the case of cooling, the operation is started in ascending order of air heat exchanger temperature, and in the case of heating, the operation is started in the order of increasing air heat exchanger temperature. Then, it moves to STEP5.

  In STEP5, the maximum value and the minimum value of the operation integration time of each outdoor unit are measured. At this time, if the time difference between the maximum value and the minimum value is within a predetermined time difference, it is considered that there is little variation in the accumulated operation time. Therefore, the number control is performed based on the first and third embodiments, and the air heat exchanger temperature is Start operation in order from low to high. If the time difference between the maximum value and the minimum value is greater than or equal to the specified time difference, it is considered that the accumulated operation time varies greatly.To reduce this variation, the operation order is set in order of decreasing the accumulated operation time of the outdoor units by unit control. Decide and start driving.

  In the above STEP 4, when the pattern 2 is selected, the pattern 2 starts to operate the outdoor unit based on the operation order determined from the local installation information. Then, it moves to STEP6.

  In STEP 6, as in Pattern 1, the maximum value and the minimum value of the operation integration time of each outdoor unit are measured. At this time, if the time difference between the maximum value and the minimum value is within a predetermined time difference, it is considered that there is little variation in the accumulated operation time. Let it begin. When the variation in the accumulated operation time is large, in order to reduce this variation, the operation order is determined in order from the least accumulated time of the outdoor units by unit control, and the operation is started.

  As described above, according to the fifth embodiment, the number control described in the first to fourth embodiments can be systematically performed, and a decrease in operation efficiency due to a short cycle can be suppressed.

  DESCRIPTION OF SYMBOLS 10 Number control apparatus, 11-19 outdoor unit (No.1-No.9 outdoor unit), 20 cables, 21 machine room, 22 air heat exchanger, 23 air blower, 24 temperature sensor, 30 anemometer.

Claims (3)

Multiple outdoor units,
A unit control device that performs control to avoid a short cycle between adjacent outdoor units;
An anemometer that measures the wind direction and wind speed at the installation location of the outdoor unit;
With
The number controller is
Installation environment information of the outdoor unit;
Installation information in which the installation position and unit number of the outdoor unit are identified;
Natural environment information of the installation location of the outdoor unit,
Wind information of wind direction and wind speed at the installation location of the outdoor unit obtained by measuring with the anemometer,
Operation accumulated time information obtained by integrating the individual operation times of the outdoor unit,
Have
Based on the installation environment information , the natural environment information , the installation information, the operation integration time information, and the wind information , a first operation block including a plurality of outdoor units so as to suppress a reduction in operation efficiency due to a short cycle. And the operation order of the outdoor units in the operation block is determined. A temperature sensor for measuring a suction temperature which is a temperature of the outside air flowing into the air heat exchanger of the outdoor unit;
The number controller is
Installation information in which the installation position and unit number of the outdoor unit are identified;
Intake temperature information of the air heat exchanger of the outdoor unit obtained by measuring with the temperature sensor,
Have
The air conditioner according to claim 1, wherein an operation order of the outdoor units is determined based on the installation information and the suction temperature information. Said first operation block, and the operating sequence of the outdoor units in of the selected operation block in second and subsequent air conditioner according to claim 1, characterized in that the ascending order of the cumulative operation time .

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