ES2967040T3 - refrigerant cycle system - Google Patents

Abstract

The present invention improves the freedom to construct a refrigerant cycle in a building or the like. A refrigerant cycle system (1) according to the present application is provided with a refrigerant cycle, a first power supply unit (30a), a second power supply unit (30b), a first transmission path (41 ) and a second transmission route. (42). Power supply units supply auxiliary power to a user unit disconnected from a power source. The first transmission path (41) connects a heat source unit (10) and the first power supply unit (30a). The second transmission path (42) connects the first power supply unit (30a) and the second power supply unit (30b). The second power supply unit (30b) is connected to the heat source unit (10) through the first power supply unit (30a). (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

refrigerant cycle system

Technical field

The present invention relates to a refrigerant cycle system.

Background of the technique

Conventionally, there is a refrigerant cycle that includes a plurality of indoor units and a plurality of power supply units for an outdoor unit. As indicated in NPL 1 ("Mitsubishi Electric Buildingair-conditioning Multi-air-conditioner System Design and Construction Manual", Mitsubishi Electric Corporation, published July 2013, p. 146, refer to the drawing), an outdoor unit, indoor units and power supply units are connected in parallel through communication lines.

JP 2016 109363 A describes a refrigerant cycle system comprising: a refrigerant cycle including a heat source unit, a first group of utilization units and a second group of utilization units; a first power supply unit differing from the heat source unit, and which is configured to, when a power source of each utilization unit of the first group of utilization units has been interrupted, supply auxiliary power to the unit of use whose energy source has been interrupted; a second power supply unit differing from the heat source unit, and which is configured to, when a power source of each utilization unit of the second group of utilization units has been interrupted, supply auxiliary power to the unit of use whose energy source has been interrupted; a first transmission line connecting the heat source unit and the first power supply unit to each other; and a second transmission line connecting the first power supply unit and the second power supply unit to each other, wherein the heat source unit, the first power supply unit and the second power supply unit They are connected in series by the first transmission line and the second transmission line so that the second power supply unit is connected to the heat source unit through the first power supply unit. Summary of the invention

technical problem

The degree of freedom is increased when a refrigerant cycle system is built in a building or similar. Solution to the problem

The invention is as defined in the claim.

Therefore, the degree of freedom increases when the refrigerant cycle system is built in a building or the like.

Brief description of the drawings

[Fig. 1] Fig.1 is a schematic diagram illustrating a configuration of a refrigerant cycle system.

[Fig. 2] Fig.2 is a schematic diagram illustrating the configuration of the refrigerant cycle system.

[Fig. 3] Fig.3 is a flow chart presenting a processing flow of the refrigerant cycle system.

Description of the achievements

A refrigerant cycle system 1 according to an embodiment of the present invention is described below. (1) General settings

Fig. 1 is a schematic diagram illustrating an example of a configuration of the refrigerant cycle system 1 according to the present embodiment. The refrigerant cycle system 1 illustrated in Fig. 1 mainly includes an outdoor unit 10, a first group of indoor units 20A including a plurality of indoor units, a second group of indoor units 20B including a plurality of indoor units, a first power supply unit 30a, a second power supply unit 30b and a transmission line 40. The first group of indoor units 20A includes three indoor units 20a, 20b and 20c. The second group of indoor units 20B includes three indoor units 20d, 20e and 20f.

The outdoor unit 10 and the respective indoor units 20a, 20b, 20c, 20d, 20e and 20f included in the refrigerant cycle system 1 are connected to each other by a refrigerant pipe 2 (see Fig. 2) to constitute a refrigerant cycle. refrigerant. The outdoor unit 10, the respective indoor units 20a, 20b, 20c, 20d, 20e and 20f, the first power supply unit 30a and the second power supply unit 30b included in the refrigerant cycle system 1 are connected between yes via transmission line 40. In this way, the respective units can communicate with each other.

The number of indoor units that can be connected to an outdoor unit is determined depending on the capacity, performance and the like of the outdoor unit. The number of indoor units that can be connected to the outdoor unit 10 according to the present embodiment is, for example, 16; However, the number is not limited to that. The arrangement of the power supply units is not limited to the arrangement illustrated in Fig. 1. The number of power supply units is not limited to the number of the arrangement. According to the present invention, it is sufficient that the refrigerant cycle system 1 includes at least one outdoor unit, at least two groups of indoor units, each of which includes one or more indoor units, and at least two refrigerant supply units. energy.

The refrigerant pipe 2 branches using a branch pipe and connects the outdoor unit 10 and the respective indoor units 20a, 20b, 20c, 20d, 20e and 20f with each other. The refrigerant flows through the refrigerant pipe 2. In this case, the type of refrigerant is not limited.

(2) Specific configuration of refrigerant cycle 1 system

The outdoor unit 10, the indoor unit 20a and the first power supply unit 30a included in the refrigerant cycle system 1 are described below with reference to Fig. 2. In this case, the illustrated refrigerant cycle system Fig. 2 partially illustrates in an enlarged manner (part surrounded by a dashed line) the refrigerant cycle system 1 illustrated in Fig. 1 to facilitate description. The description is provided according to the present embodiment based on the assumption that the respective indoor units 20b, 20c, 20d, 20e and 20f included in the refrigerant cycle system 1 have configurations similar to that of the indoor unit 20a illustrated in Fig 2. and the second power supply unit 30b included in the refrigerant cycle system 1 has a configuration similar to that of the first power supply unit 30a illustrated in Fig. 2.

(2-1) Outdoor unit 10

As illustrated in Fig. 2, the outdoor unit 10 which serves as the heat source unit is connected to a power source 11 which is a commercial power source and which serves as the main power source of the outdoor unit 10. The outdoor unit 10 includes an outdoor heat exchanger 12, an outdoor fan 13, a compressor 14, an outdoor control unit 15 and a communication unit 16. The outdoor heat exchanger 12 condenses or evaporates the refrigerant flowing through the refrigerant tube 2 to carry out heat exchange. The outdoor fan 13 sends air to the outdoor heat exchanger 12 to cause the refrigerant to exchange heat with air. The compressor 14 compresses and circulates the refrigerant in the refrigerant pipe 2. The outdoor control unit 15 controls the entire outdoor unit 10 and the refrigerant cycle system 1. The communication unit 16 communicates with the other units.

The respective configurations included in the outdoor unit 10 operate when power is supplied from the power source 11 through a power source line.

(2-2) Indoor unit 20a

The indoor unit 20a which serves as the utilization unit is connected to a power source 21a which is a commercial power source and which serves as the main power source of the indoor unit 20a. The indoor unit 20a includes an indoor heat exchanger 22a, an indoor fan 23a, an expansion valve 24a, an indoor control unit 25a, a communication unit 26a and an interruption detection unit 27a. The indoor heat exchanger 22a condenses or evaporates the refrigerant flowing through the refrigerant tube 2 to realize heat exchange. The indoor fan 23a sends air to the indoor heat exchanger 22a to cause the refrigerant to exchange heat with the air. The expansion valve 24a adjusts the amount of refrigerant flowing through the refrigerant pipe 2. The indoor control unit 25a controls the entire indoor unit 20a. The communication unit 26a communicates with the other units. When it is detected that the power supply from the power source 21a has been interrupted, the interruption detection unit 27a transmits an interruption signal to the outdoor control unit 15 of the outdoor unit 10. The interruption signal includes a signal to notify that the main power supply has been interrupted, and the identification information of the indoor unit whose main power supply has been interrupted. Indoor unit identification information is information unique to each indoor unit. The identification information of each of the indoor units is stored in the outdoor control unit 15 of the outdoor unit 10.

In the case where the power supply from the power source 21a has not been interrupted, the respective configurations included in the indoor unit 20a operate when power is supplied from the power source 21a through a power supply line. energy.

(2-3) First power supply unit 30a

The first power supply unit 30a is connected to a power source 31a which is a commercial power source and which serves as the main power source of the first power supply unit 30a. The first power supply unit 30a includes a power supply control unit 32a that controls the entire power supply unit 30a, and a communication unit 33a that communicates with the other units.

The respective configurations included in the first power supply unit 30a operate when power is supplied from the power source 31a through a power source line.

The number of indoor units to which a power supply unit can supply power simultaneously is determined in advance depending on the performance and the like of the power supply unit. Please note that the power supplied from the power supply unit to an indoor unit is used as auxiliary power.

The auxiliary power is mainly used to adjust the opening degree of the expansion valve of the indoor unit. In addition, the auxiliary power can be used for various actuator operations in the indoor unit. Examples of actuator operations include an operation of closing a grill panel included in the indoor unit and an operation of collecting various data related to the indoor unit. Actuator operations performed using auxiliary power are preconfigured operations.

The power supply unit that supplies auxiliary power to each indoor unit is configured in advance. When the power supply from the main power supply to each indoor unit is interrupted, the configured power supply unit supplies auxiliary power.

For example, in Fig. 1, the first power supply unit 30a supplies auxiliary power to the indoor units 20a, 20b and 20c. The second power supply unit 30b supplies auxiliary power to the indoor units 20d, 20e and 20f. The processing of a power supply unit to supply auxiliary power to an indoor unit will be described in detail later.

(2-4) Transmission Line 40

As illustrated in Fig. 1, transmission line 40 connects the respective units included in the refrigerant cycle system 1.

The transmission line 40 is normally used primarily for communication and allows communication between the respective communication units. Furthermore, the transmission line 40 has the function of a power source line to supply auxiliary power from a power supply unit to an indoor unit in the case where the main power source of the indoor unit has been interrupted. In other words, the transmission line 40 is used for both transmission and power supply.

In the present embodiment, as illustrated in Fig. 1, the transmission line 40 includes a first transmission line 41, a second transmission line 42 and a third transmission line 43.

The first transmission line 41 connects the outdoor unit 10 and the first power supply unit 30a in series.

The second transmission line 42 connects the first power supply unit 30a and the second power supply unit 30b in series. Specifically, the second transmission line 42 includes transmission lines 42a, 42b, 42c and 42d that connect the respective units, and connect the first power supply unit 30a, the respective indoor units 20a, 20b and 20c included in the first group of indoor units 20A, and the second power supply unit 30b. In this case, it is sufficient that the second transmission line 42 connects the first power supply unit 30a and the second power supply unit 30b in series, and the connection manner of the respective indoor units 20a, 20b and 20c included in the first inner unitary group 20A it is not limited. The indoor units 20a, 20b and 20c are connected, for example, in sequential order.

The third transmission line 43 connects in series the second power supply unit 30b and a third power supply unit (not shown). Specifically, the third transmission line 43 includes transmission lines 43a, 43b, 43c and 43d connecting the respective units, and connects the second power supply unit 30b, the respective indoor units 20d, 20e and 20f included in the second group of indoor units 20B, and the third power supply unit. In this case, it is sufficient that the third transmission line 43 connects the second power supply unit 30b and the third power supply unit in series, and the connection manner of the respective indoor units 20d, 20e and 20f included in the second group of indoor units 20B is not limited.

(3) Refrigerant cycle system processing 1

Fig. 3 is a flow chart illustrating an example of processing of the refrigerant cycle system 1 according to the embodiment of the present invention. The flow chart presents a case where the main power supply to the indoor unit 20a included in the refrigerant cycle system 1 illustrated in Fig. 1 is interrupted and auxiliary power is supplied to the indoor unit 20a from the first power supply unit 30a included in the refrigerant cycle system 1 through transmission line 40.

First, in step S1, the indoor unit 20a starts various types of processing in a state supplied with power from the power source 21a. The indoor unit 20a in this state operates the respective settings and can perform air conditioning operation such as cooling or heating.

In step S2, the interruption detection unit 27a of the indoor unit 20a determines whether or not the power supply from the power source 21a has been interrupted. In step S2, when the interruption detection unit 27a does not detect a power interruption from the power source 21 a (S2: NO), the indoor unit 20a continues the air conditioning operation and the interruption detection unit 27a determination continues.

On the contrary, in step S2, when the interruption detection unit 27a detects a power interruption from the power source 21a (S2: YES), the indoor unit 20a switches the power supply for the indoor unit 20a from the power source 21a to the first power supply unit 30a (step S3). In other words, the indoor unit 20a starts auxiliary power supply from the first power supply unit 30a through the transmission line 40.

In step S4, the indoor unit 20a sends the interrupt signal to the outdoor unit 10 through the transmission line 40.

In step S5, the outdoor control unit 15 of the outdoor unit 10 transmits an instruction of adjusting the opening degree of the expansion valve 24a to the indoor unit 20a. The opening degree adjustment instruction is an instruction to fully open the expansion valve 24a, to fully close the expansion valve 24a, to increase the opening degree, or to decrease the opening degree. Therefore, an oil return operation of the indoor unit 20a or the like can be performed. The outdoor control unit 15 of the outdoor unit 10 may transmit operating instructions to command various operations of the actuator to the indoor unit 20a. The indoor control unit 25a of the indoor unit 20a controls the various types of actuators based on the operating instructions.

In step S6, the indoor control unit 25a of the indoor unit 20a adjusts the opening degree of the expansion valve 24a based on the opening degree adjustment instructions of the outdoor unit 10.

In step S7, the interruption detection unit 27a of the indoor unit 20a determines whether or not the power to the power source 21a has been interrupted. In other words, it is determined whether or not power has been recovered from the main power source. In step S7, when the interruption detection unit 27a detects a power interruption from the power source 21 a (S7: YES), the interruption detection unit 27a repeats the determination and continues the power supply from the first 30a power supply unit.

On the contrary, in step S7, when the interruption detection unit 27a does not detect a power interruption from the power source 21a (S7: NO), in other words, when the power supply from the source has been resumed main power supply, the power supply source of the indoor unit 20a is switched from the first power supply unit 30a to the power supply 21a (step S8).

With the processing described above, the processing of the auxiliary power supply to the indoor unit 20a from the first power supply unit 30a through the transmission line 40 in the case where the main power source of the indoor unit 20th has been interrupted is finished.

(4) Features

The refrigerant cycle system 1 according to the present embodiment includes the refrigerant cycle, the first power supply unit 30a, the second power supply unit 30b, the first transmission line 41 and the second transmission line 42. The refrigerant cycle includes the outdoor unit 10 serving as the heat source unit, the first group of indoor units 20A serving as the first group of utilization units, and the second group of indoor units 20B serving as the second group of utilization units. When the power source of each of the indoor units 20a, 20b and 20c of the first group of indoor units 20A has been interrupted, the first power supply unit 30a supplies auxiliary power to the utilization unit whose power source has been interrupted. disrupted. The first power supply unit 30a is a different unit from the outdoor unit 10. When the power supply of each of the utilization units 20d, 20e and 20f of the second group of indoor units 20B has been interrupted, the second Power supply unit 30b supplies auxiliary power to the utilization unit whose power source has been interrupted. The second power supply unit 30b is a different unit from the outdoor unit 10. The first transmission line 41 connects the outdoor unit 10 and the first power supply unit 30a to each other. The second transmission line 42 connects the first power supply unit 30a and the second power supply unit 30b to each other. The second power supply unit 30b is connected to the outdoor unit 10 through the first power supply unit 30a.

Furthermore, in the refrigerant cycle system 1 according to the present embodiment, the outdoor unit 10, the first power supply unit 30a and the second power supply unit 30b are connected in series by the first transmission line 41 and the second transmission line 42.

When the outdoor unit and the power supply unit can only be connected in parallel, the length of the transmission line connecting the outdoor unit and the power supply unit to each other may be too long. In such a case, the construction of the wiring requires time and effort, which leads to an increase in the construction cost.

In the refrigerant cycle system 1 according to the present embodiment, the outdoor unit 10, the first power supply unit 30a and the second power supply unit 30b are connected in series by the first transmission line 41 and the second line transmission 42. Therefore, the construction of wiring between the respective units can be done efficiently.

Therefore, the outdoor unit and the power supply unit can be arranged at locations further apart than those in the related art. Consequently, the degree of freedom increases when the refrigerant cycle system is built in a building or the like.

(5)

List of reference signs

1 refrigerant cycle system

10 heat source unit

20A first group of utilization units

20B second group of utilization units

20a, 20b, 20c, 20d, 20e, 20f Unit of use

21a, 21b, 21c, 21d, 21e, 21f power supply

30th first power supply unit

30b second power supply unit

41 first transmission line

42 second transmission line

Appointment list

Non-patent bibliography

NPL 1: "Mitsubishi Electric Building-air-conditioning Multi-air-conditioner System Design and Construction Manual", Mitsubishi Electric Corporation, published July 2013, p. 146

Claims (1)

1. A refrigerant cycle system (1) comprising: a refrigerant cycle including a heat source unit (10), a first group of utilization units (20A) and a second group of utilization units (20B); a first energy supply unit (30a) that differs from the heat source unit (10), and that is configured so that, when an energy source (21a, 21b, 21c) of each utilization unit (20a, 20b , 20c) of the first group of utilization units (20A) has been interrupted, supplying auxiliary power to the utilization unit whose power source has been interrupted; a second energy supply unit (30b) that differs from the heat source unit (10), and which is configured to, when an energy source (21d, 21e, 21f) of each utilization unit (20d, 20e , 20f) of the second group of utilization units (20B) has been interrupted, supplying auxiliary power to the utilization unit whose power source has been interrupted; a first transmission line (41) connecting the heat source unit (10) and the first power supply unit (30a) to each other; and a second transmission line (42) connecting the first power supply unit (30a) and the second power supply unit (30b) to each other, where The heat source unit (10), the first power supply unit (30a), and the second power supply unit (30b) are connected in series by the first transmission line (41) and the second transmission line. transmission (42) so that the second power supply unit (30b) is connected to the heat source unit (10) through the first power supply unit (30a), characterized by The second transmission line (42) includes a plurality of transmission lines (42a, 42d) so that the first power supply unit (30a), the utilization unit (20a) included in the first group of utilization units (20A), and the second power supply unit (30b) are connected in sequential order.