ES2753852T3 - Air conditioning device - Google Patents

Abstract

An air conditioning apparatus that includes an indoor heat exchanger (32) and is configured to allow the indoor heat exchanger (32) to function as a radiator for refrigerant and perform a heating operation, comprising: a distributor (81 ) including: a distributor body (81a) positioned in the vicinity of a refrigerant outlet of the indoor heat exchanger (32) that functions as a radiator; and a plurality of distribution pipes (81b) branching from the distributor body (81a) and each connected to one of a plurality of refrigerant paths (P) formed in the indoor heat exchanger (32); and a temperature sensor (183) configured to detect a saturation temperature of the refrigerant flowing through the indoor heat exchanger (32), wherein the temperature sensor (183) is mounted on a center height of the heat exchanger. internal heat (32) in use state or the distributor body (81a), characterized in that in a particular path, between the plurality of paths of refrigerant (P), in which the temperature sensor (183) is mounted, The temperature sensor (183) is mounted on a gas side end side of the particular path, with respect to a flow of refrigerant flowing through the particular path.

Description

DESCRIPTION

Air conditioning device

Technical field

The present invention relates to an air conditioning apparatus and, in particular, to an air conditioning apparatus that allows an indoor heat exchanger to function as a radiator for the refrigerant to perform a heating operation.

Background of the Invention

In recent years, there have been calls for improvements in operational efficiency and indication of consumption efficiency in real-life environments, particularly at low load. For this purpose, it is necessary to allow an operating state to appear with circulation quantities in a low range for the calculation of a minimum heating capacity. During the calculation, the accumulation of liquid tends to occur, since a refrigerant circulation quantity is less than that of an operation at an intermediate capacity.

As a countermeasure to prevent liquid pooling, for example, a patent literature (JP-A-H5-280808) discloses a heat pump system that adopts a method of opening an electric expansion valve to temporarily eliminate the liquid pool.

JP H07 127942 A discloses an air conditioning apparatus according to the preamble of appended claim 1 which includes an indoor heat exchanger and is configured to allow the indoor heat exchanger to function as a radiator for coolant and perform a heating operation, comprising: a distributor including: a distributor body located near a coolant outlet of the indoor heat exchanger that functions as a radiator; and a plurality of distribution pipes branching from the distributor body and each connected to one of a plurality of refrigerant paths formed in the indoor heat exchanger; and a temperature sensor configured to detect a saturation temperature of the coolant flowing through the indoor heat exchanger, in which the temperature sensor is mounted on a center height of the indoor heat exchanger in use or body state dealer.

US 2014/116078 A1 discloses an air conditioning apparatus having an external heat exchanger including the capillary tubes and an external heat exchange temperature sensor mounted on the capillary tube.

Summary of the invention

<Technical problem>

Meanwhile, in a conventional air conditioning apparatus, a mounting position of a thermistor to an indoor heat exchanger is in a lower portion of the heat exchanger, which is closer when a front panel of an indoor unit is opened, from the point of view of the harness lengths of electrical components, maintenance and the like.

However, in the event that an operation is implemented in fewer rotations of the compressor at the output of a minimum heating capacity, while the thermistor is mounted on the lower portion of the heat exchanger in the conventional manner, the Liquid accumulation occurs in a portion corresponding to the mounting position of the thermistor. Therefore, even if an electrical expansion valve is opened to be controlled, the accumulation of liquid cannot be eliminated, causing failure to detect an accurate saturation temperature under the influence of accumulation of liquid. Therefore, the control of the subcooling is hampered and it is detected that a high pressure is lower than it is; these are not preferable from a security point of view.

Alternatively, as a countermeasure, it is possible to provide a pressure sensor to convert a value detected by the pressure sensor to a saturation temperature. However, it is not advisable to provide a pressure sensor, as this would increase product costs.

An object of the present invention is to provide an air conditioning apparatus that allows an indoor heat exchanger to function as a radiator for the refrigerant to carry out a heating operation and that allows detection of an accurate saturation temperature, even if fluid build-up occurs in an operational state with circulating amounts in a low range.

<Solution to the problem>

An air conditioning apparatus according to a first aspect of the present invention is an air conditioning apparatus according to the attached claim 1. The air conditioning apparatus according to the first aspect includes an indoor heat exchanger and is configured to allow the Indoor heat exchanger functions as a radiator for coolant to perform a heating operation. The air conditioning apparatus according to the first aspect comprises a distributor and a temperature sensor. The distributor includes a distributor body and a plurality of distribution pipes. The distributor body is placed near a coolant outlet of the indoor heat exchanger that functions as a radiator. The distribution pipes branch off from the distributor body and each is connected to one of a plurality of refrigerant paths formed in the indoor heat exchanger. The temperature sensor is configured to detect a saturation temperature of the coolant flowing through the indoor heat exchanger. The temperature sensor is mounted on a center height of the interior heat exchanger in use or of the distributor body.

When an operation with a smaller number of compressor rotations is implemented to produce a minimum heating capacity, the accumulation of liquid tends not to occur in higher refrigerant paths than the distributor body, while the accumulation of liquid tends to occur at lower coolant paths than the distributor body. This would be caused by the liquid in the coolant paths lower than the distributor body, which cannot rise to the distributor body under the influence of gravity, as the amount of circulating coolant is reduced.

However, even when an operation is implemented in a smaller number of compressor rotations at the output of a minimum heating capacity to reduce an amount of circulating refrigerant, since the accumulation of liquid does not occur above the center in height From the indoor heat exchanger or into the distributor body, this air conditioning apparatus allows the temperature sensor mounted in the region described above to detect an accurate saturation temperature.

Accordingly, the likelihood of subcooling control impediment is eliminated, whereby the control of opening of an electric valve in the conventional manner need not be performed solely for the removal of liquid accumulation. Of course, no pressure sensor is needed.

Furthermore, in the air conditioning apparatus according to the first aspect, in a particular path, among the plurality of refrigerant paths, in which the temperature sensor is mounted, the temperature sensor is mounted on one side of gas side end of the particular path, with respect to a flow of refrigerant flowing through the particular path.

Since the temperature sensor is mounted not on a liquid side, but on the end side of the gas side with respect to the flow of the refrigerant flowing through the refrigerant path, this air conditioning apparatus prevents a Saturation temperature fails to be detected when subcooling occurs throughout the system.

An air conditioning apparatus according to a second aspect of the present invention is the air conditioning apparatus according to the first aspect, wherein: the indoor heat exchanger has a first side end portion and a second portion lateral end; each of the plurality of refrigerant paths makes a round trip between the first side end portion and the second side end portion to form a first U-portion in the first side-end portion and a second U-portion in the second lateral end portion; the plurality of distribution pipes are connected to the plurality of refrigerant paths in the second lateral end portion; and the temperature sensor is mounted on the second U-shaped portion.

An air conditioning apparatus according to a third aspect of the present invention is the air conditioning apparatus according to the first or second aspect, wherein: when a height direction of the indoor heat exchanger in the state of use is oriented in the top-down direction, the plurality of refrigerant paths are arranged in the up and down direction of the internal heat exchanger; and the temperature sensor is mounted in one path, between the plurality of refrigerant paths, in a range that occupies 30% of all refrigerant paths down from the topmost row refrigerant path. This air conditioning apparatus allows for safer detection of an accurate saturation temperature.

An air conditioning apparatus according to a fourth aspect of the present invention is the air conditioning apparatus according to the third aspect, in which the temperature sensor is mounted in the path of the topmost refrigerant row between the plurality of refrigerant paths. This air conditioning apparatus allows for safer detection of an accurate saturation temperature.

An air conditioning apparatus according to a fifth aspect of the present invention is the air conditioning apparatus according to any one of the first to fourth aspects, further comprising: a compressor configured to compress refrigerant at low pressure and discharge a high-pressure coolant that flows through the indoor heat exchanger; and a controller, wherein: the controller is configured to control the compressor to operate continuously for 30 seconds or more at a lower number of compressor rotational capacities to produce a minimum heating capacity less than 45% of a nominal capacity. heating it.

With a compressor that has a range sufficient to allow a minimum heating operating state to simply appear in the course of events to implement an operation according to a load, this air conditioning apparatus allows for the spontaneous appearance of an operating state of minimal heating.

<Advantageous Effects of the Invention>

Even when an operation is implemented in a smaller number of compressor rotations at the output of a minimum heating capacity to reduce a quantity of circulating refrigerant, since the accumulation of liquid does not occur above the height center of the heat exchanger. heat inside or in the distributor body, the air conditioning apparatus according to the first aspect of the present invention allows the temperature sensor mounted in the region described above to detect an accurate saturation temperature. Accordingly, the likelihood of subcooling control impediment is eliminated, whereby the control of opening of an electric valve in the conventional manner need not be performed solely for the removal of liquid accumulation. Of course, no pressure sensor is needed.

Furthermore, since the temperature sensor is mounted not on a liquid side, but on the end side of the gas side with respect to the flow of the refrigerant flowing through the refrigerant path, the air conditioning apparatus according with the first aspect of the present invention it prevents a saturation temperature from failing to be detected when subcooling occurs throughout the system.

Since the temperature sensor is mounted on one path, between the plurality of paths, in an interval that occupies 30% of all paths down from a higher row path, the air conditioning apparatus according to the A third aspect of the present invention enables safer detection of an accurate saturation temperature.

Since the temperature sensor is mounted in the uppermost row path among the plurality of paths, the air conditioning apparatus according to the fourth aspect of the present invention allows for safer detection of an accurate saturation temperature.

With a compressor having a range sufficient to allow a minimum heating operating state to simply appear in the course of events to implement an operation according to a load, the air conditioning apparatus according to the fifth aspect of the present Invention allows the spontaneous appearance of a minimal heating operating state.

Brief description of the drawings

Fig. 1 is a diagram of a piping system showing a structure of a refrigerant circuit of an air conditioning apparatus according to an embodiment of the present invention.

Fig. 2 is an external perspective view of an indoor unit of the air conditioning apparatus.

Fig. 3 is a vertical cross-sectional view of the indoor unit of the air conditioning apparatus.

Fig. 4 is a plan view of the interior of the indoor unit of the air conditioning apparatus as seen from the top surface thereof.

Fig. 5 is a front view of an indoor heat exchanger when a first side end portion is front.

Figure 6 schematically shows a positional relationship of a distributor with respect to the height direction of an indoor heat exchanger in use state.

Fig. 7 is a plan view of a heat transfer tube of the indoor heat exchanger.

Figure 8 is a graph showing temperature distributions in the indoor heat exchanger during operation at minimum heating capacity.

Figure 9 schematically shows, for an indoor heat exchanger used in a floor model indoor unit, a positional relationship of a distributor with respect to the height direction of the indoor heat exchanger in use state.

Figure 10 is a graph showing temperature distributions in the indoor heat exchanger during operation at minimum heating capacity.

Figure 11 shows schematically, an indoor heat exchanger used in a two-way indoor unit, a positional relationship of a distributor with respect to the height direction of an indoor heat exchanger in use state.

Description of embodiments

Next, they will describe preferred example embodiments of the present invention with reference to the drawings. The following embodiments are specific examples of the present invention and are not intended to limit the technical scope of the present invention.

(1) Air conditioning system 10

Fig. 1 is a diagram of a piping system showing a structure of a refrigerant circuit C of an air conditioning apparatus 10 according to an embodiment of the present invention. In Figure 1, the air conditioning apparatus 10 cools and heats the indoor air. As shown in Figure 1, the air conditioning apparatus 10 includes an outdoor unit 11 installed outdoors and an indoor unit 20 installed indoors. The outdoor unit 11 and the indoor unit 20 are connected to each other through two communication pipes 2, 3, thus forming the refrigerant circuit C in this air conditioning apparatus 10. In the refrigerant circuit C, the refrigerant injected into it circulates to perform a vapor compression refrigeration cycle.

(1-1) Outdoor unit 11

The outdoor unit 11 is provided with a compressor 12, an outdoor heat exchanger 13, an outdoor expansion valve 14, and a four-way switching valve 15.

(1-1-1) Compressor 12

Compressor 12 compresses the low pressure refrigerant, and discharges the compressed high pressure refrigerant in this way. In compressor 12, a compression mechanism such as a displacement or rotary compression mechanism is driven by a motor of compressor 12a. The compressor motor 12a is configured to have an operating frequency that can be varied by means of an inverter.

(1-1-2) Outdoor heat exchanger 13

The outdoor heat exchanger 13 is a fin and a tube heat exchanger. An outdoor fan 16 is installed in the vicinity of the outdoor heat exchanger 13. In the outdoor heat exchanger 13, the air carried by the outdoor fan 16 exchanges heat with the refrigerant.

(1-1-3) External expansion valve 14

The outer expansion valve 14 is an electronic expansion valve having a variable degree of opening. The external expansion valve 14 is arranged on the downstream side of the external heat exchanger 13 in a direction of flow of the refrigerant in the refrigerant circuit C during a cooling operation.

During a cooling operation, the opening degree of the outer expansion valve 14 is in a fully open state. On the other hand, during a heating operation, the opening degree of the external expansion valve 14 is adjusted to reduce the pressure of the refrigerant flowing to the external heat exchanger 13 to a pressure that allows the refrigerant to evaporate into the external heat exchanger 13 (i.e. an evaporation pressure).

(1-1-4) Four-way switch valve 15

The four-way switch valve 15 includes a first to fourth ports. In the four-way switch valve 15, the first port is connected to a discharge side of compressor 12, the second port is connected to a suction side of compressor 12, the third port is connected to an end portion of the side of gas from the external heat exchanger and the fourth port is connected to a gas side shutoff valve 5.

The four-way switch valve 15 is switchable between a first state (a state indicated by the continuous curves in Figure 1) and a second state (a state indicated by the discontinuous curves in Figure 1). In the four-way switch valve 15 in the first state, the first port communicates with the third port, and the second port communicates with the fourth port. In the four-way switch valve 15 in the second state, the first port communicates with the fourth port, and the second port communicates with the third port.

(1 1-5) Outdoor fan 16

The outdoor fan 16 is configured with a propeller fan driven by an outdoor fan motor 16a. The outdoor fan motor 16a is configured to have the number of rotations that can be varied by an inverter.

(1-1-6) Liquid communication pipe 2 and gas communication pipe 3

The two communication pipes are configured with a liquid communication pipe 2 and a gas communication pipe 3. One end of the liquid communication pipe 2 is connected to a liquid-side shut-off valve 4, and the other end thereof is connected to a portion of the liquid side end of an indoor heat exchanger 32. One end of the gas communication pipe 3 is connected to the gas side shutoff valve 5, and the other end of the It is connected to a gas end end portion of the indoor heat exchanger 32.

(1-2) Indoor unit 20

Indoor unit 20 is provided with an indoor heat exchanger 32, an indoor expansion valve 39, an indoor fan 27, and a coolant temperature sensor 183.

(1-2-1) Indoor heat exchanger 32

The indoor heat exchanger 32 is a fin and a tube heat exchanger. The indoor heat exchanger 32 is installed near the indoor fan 27.

(1-2-2) Inner expansion valve 39

In the refrigerant circuit C, the interior expansion valve 39 is connected to the liquid side end side of the interior heat exchanger 32. The interior expansion valve 39 is configured with an electronic expansion valve having a variable degree of opening.

(1-2-3) Indoor fan 27

The indoor fan 27 is a centrifugal blower driven by an indoor fan motor 27a. The indoor fan motor 27a is configured to have the number of rotations that can be varied by an inverter. (1-2-4) Coolant temperature sensor 183

The coolant temperature sensor 183 is mounted at a predetermined position of the indoor heat exchanger 32, and detects a temperature of the coolant in a two-phase gas-liquid state flowing through the indoor heat exchanger 32. The conditioning apparatus Air cooler 10 has its cooling capacity and heating capacity adjusted based on a temperature detected by this coolant temperature sensor 183.

(1-3) 800 Controller

A controller 800 is configured with an outer side controller 801 and an inner side controller 803. The outer side controller 801 is arranged in the outdoor unit 11, and controls the operations of the respective components. The indoor side controller 803 is arranged in the indoor unit 20, calculates a saturation temperature from a value detected by the coolant temperature sensor 183, and controls the number of rotations of the indoor fan 27.

The outer side controller 801 and the inner side controller 803 each have a microcomputer, a memory, and the like, and can send and receive control signals and the like to each other.

(2) Detailed structure of indoor unit 20

Fig. 2 is an external perspective view of the indoor unit 20 of the air conditioning apparatus 10. Fig. 3 is a vertical cross sectional view of the indoor unit 20 of the air conditioning apparatus 10. Fig. 4 is a plan view of the interior of the indoor unit 20 of the air conditioning apparatus 10 as seen from the top surface thereof.

In Figures 2, 3 and 4, the indoor unit 20 of the present embodiment is configured with a ceiling mounted unit. The indoor unit 20 includes an indoor unit body 21 and an ornamental panel 40 mounted on the lower portion of the indoor unit body 21.

(2-1) Body of indoor unit 21

As shown in Figures 2 and 3, the body of the indoor unit 21 includes a box-shaped housing 22 having a substantially rectangular parallelepiped shape. A liquid side connection pipe 6 and a gas side connection pipe 7, which are connected to the internal heat exchanger 32, pass through a side panel 24 of the housing 22 (see FIG. 4). The liquid side connection pipe 6 is connected to the liquid communication pipe 2, and the gas side connection pipe 7 is connected to the gas communication pipe 3.

The housing 22 houses the interior fan 27, a hood mouth 31, the interior heat exchanger 32, and a drain pan 36.

As shown in Figures 3 and 4, the indoor fan 27 is centrally disposed within the housing 22. The indoor fan 27 includes the indoor fan motor 27a and an impeller 30. The indoor fan motor 27a is supported on the panel upper casing 22. Impeller 30 is configured with a plurality of turbo blades 30a arranged in a direction of rotation of drive shaft 27b.

The bell mouth 31 is arranged below the internal fan 27. The bell mouth 31 has a circular opening at each of its upper and lower ends, and is formed in a tubular shape so that the region of the opening increases towards the ornamental panel 40. The interior space of the hood opening 31 communicates with a space for housing the interior fan impeller 27.

As shown in Figure 4, in the interior heat exchanger 32, bent heat transfer tubes are arranged so as to surround the interior fan 27. The interior heat exchanger 32 is installed on the upper surface of the drain pan. 36 so that it lifts up. The air that blows laterally from the indoor fan 27 passes through the indoor heat exchanger 32. The indoor heat exchanger 32 constitutes an evaporator that cools the air during a cooling operation, and also constitutes a condenser (a radiator) that heats the air during a heating operation.

(2-2) Ornamental panel 40

The ornamental panel 40 is mounted on the bottom surface of the housing 22. The ornamental panel 40 includes a panel body 41 and a suction grille 60.

Panel body 41 has a rectangular frame shape in plan view. Panel body 41 has one panel-side suction flow channel 42 and four panel-side exhaust flow channels 43.

As shown in Figure 3, the panel side suction flow channel 42 is formed in a central portion of the panel body 41. A suction port 42a facing the room space is formed at the lower end of the channel panel side suction flow filter 42. A dust collection filter 45 is provided to trap dirt and dust in the air drawn through the suction port 42a in the panel side suction flow channel 42.

The respective panel-side exhaust flow channels 43 are formed outside the panel-side suction flow channel 42, such that they surround the panel-side suction flow channel 42. Each of the flow channels panel-side exhaust flow 43 extends along one of the four associated sides of the panel-side suction flow channel 42. An outlet port 43a is oriented towards the room space at the lower end of each of the expulsion flow channels on the panel side 43.

Suction grille 60 is mounted at the lower end of panel side suction flow channel 42 (i.e., suction port 42a).

(3) Operations

Next, the operations of the air conditioning apparatus 10 according to the present embodiment will be described. The air conditioning apparatus 10 selectively performs a cooling operation and a heating operation.

(3-1) Cooling operation

During a cooling operation, the four-way switching valve 15 is switched to the state indicated by the continuous curves in FIG. 1 to operate the compressor 12, the indoor fan 27, and the outdoor fan 16. Thus, the refrigerant circuit C performs a refrigeration cycle in which the outdoor heat exchanger 13 functions as a condenser and the indoor heat exchanger 32 functions as an evaporator.

Specifically, the high pressure refrigerant compressed by the compressor 12 flows through the outdoor heat exchanger 13 and exchanges heat with the outside air. In the outdoor heat exchanger 13, the high pressure coolant dissipates heat into the outside air and consequently condenses. The refrigerant thus condensed in the outdoor heat exchanger 13 is passed to the indoor unit 20. In the indoor unit 20, the refrigerant has its pressure reduced by the indoor expansion valve 39, and subsequently flows through the indoor heat exchanger 32 .

In the indoor unit 20, the indoor air flows up through the suction port 42a, the panel side flow suction channel 42, and the interior of the hood mouth 31 in this order, and then sucked in the impeller housing space of the internal fan 27. Air in the impeller housing space is carried by the impeller 30 and is exhausted radially outward. This air passes through the indoor heat exchanger 32 and exchanges heat with the refrigerant. In the indoor heat exchanger 32, the refrigerant absorbs heat from the indoor air and evaporates, thereby cooling the air.

The air cooled by the indoor heat exchanger 32 divides and flows within the respective body side exhaust flow channels 37, and then flows downward through the exhaust side flow channels. panel 43, and is subsequently supplied through outlet ports 43a in the room space. The refrigerant evaporated in the indoor heat exchanger 32 is sucked into the compressor 12, and is compressed there again.

(3-2) Heating operation

During a heating operation, the four-way switching valve 15 is switched to the state indicated by the dashed curves in FIG. 1 to operate the compressor 12, the indoor fan 27 and the outdoor fan 16. Thus, the refrigerant circuit C performs a refrigeration cycle in which the indoor heat exchanger 32 functions as a condenser and the outdoor heat exchanger 13 functions as an evaporator.

Specifically, the high-pressure refrigerant compressed by compressor 12 flows through indoor heat exchanger 32 of indoor unit 20. In indoor unit 20, indoor air flows upward through suction port 42a, the flow channel. flow suction from the panel side 42, and the interior space of the bell mouth 31 in this order, and then sucked into the housing space of the impeller of the internal fan 27. Air in the housing of the impeller is carried by impeller 30 and is ejected radially outward. This air passes through the indoor heat exchanger 32 and exchanges heat with the refrigerant. In the indoor heat exchanger 32, the refrigerant dissipates the heat into the indoor air and condenses, thereby heating the air.

The air heated by the indoor heat exchanger 32 divides and flows into the respective body-side exhaust flow channels 37, and then flows downward through the panel-side exhaust flow channels 43, and is subsequently supplied through outlet ports 43a in the room space. The condensed refrigerant in the indoor heat exchanger 32 has its pressure reduced by the outdoor expansion valve 14, and subsequently flows through the outdoor heat exchanger 13. In the outdoor heat exchanger 13, the refrigerant absorbs heat from the outside air and evaporates. The refrigerant evaporated in the external heat exchanger 13 is sucked into the compressor 12, and is compressed there again.

(4) Gas side pipe 70, liquid side pipe 80 and its surrounding structures

Next, a gas side pipeline 70 and a liquid side pipeline 80 housed in the indoor unit 20, and its surrounding structures, will be described.

As shown in Figure 4, the indoor heat exchanger 32 has a first side end portion 32a and a second side end portion 32b. The first side end portion 32a is formed at one of the side ends of the interior heat exchanger 32 in the longitudinal direction of the heat transfer tubes thereof. The second side end portion 32b is formed at the other side end of the interior heat exchanger 32 in the longitudinal direction of the heat transfer tubes thereof. The gas side piping 70 and the liquid side piping 80 are installed in a pipe receiving space S between the first and second side end portions 32a, 32b of the indoor heat exchanger 32.

(4-1) Gas side tube 70

Fig. 5 is a front view of the indoor heat exchanger 32 when the first side end portion 32a is front. In Figures 4 and 5, the gas side tube 70 is arranged and extends between the gas side end portion of the indoor heat exchanger 32 in the first side end portion 32a and the side connection tube of the gas 7 described above. The gas side pipeline 70 includes a head 71, which is connected to the interior heat exchanger 32, and a gas transmission pipeline 72 connected to the head 71 and the gas side connection pipeline 7 therebetween.

The head 71 is arranged in the area of the first side end of the part 32a of the internal heat exchanger 32. The head 71 includes a head body 71a and a plurality of branched pipes 71b that branch from the body of the head 71a.

(4-1-1) Head body 71a

The head body 71a extends along the first end portion 32a of the indoor heat exchanger 32 in the up and down direction. In other words, the head body 71a is parallel to the first side end portion 32a with a predetermined distance from the first side end portion 32a of the indoor heat exchanger 32.

During a cooling operation, the body of the head 71a allows the refrigerant flowing out of the respective branch pipes 71b to join. On the other hand, during a heating operation, the body of the head 71a allows the refrigerant that flows out of the gas transmission pipe 72 to divide and flow into the respective bypass pipes 71b.

(4-1-2) Bypass pipes 71b

The bypass pipes 71b are arranged between the body of the head 71a and the first lateral end portion 32a of the internal heat exchanger 32. The bypass pipes 71b are arranged along the side surface of head body 71a (i.e. arranged in the up and down direction) to be parallel to each other. One end of each of the bypass pipes 71b is connected to an associated one of the heat transfer tubes (ie, refrigerant paths P) in the first side end portion 32a of the indoor heat exchanger 32. The other end each of the bypass pipes 71b is connected to the head body 71a, and communicates with the interior of the head body 71a.

(4-2) Liquid side piping 80

The liquid side pipeline 80 is arranged and extends between the liquid side end portion of the interior heat exchanger 32 in the second lateral end portion 32b and the liquid side connection pipeline 6 described above. The liquid side pipe 80 includes a distributor 81 and a liquid transmission pipe 82 connected to the distributor 81 and the liquid side connection pipe 6 therebetween. The distributor 81 is placed in the vicinity of the second lateral end portion 32b of the indoor heat exchanger 32. The distributor 81 includes a distributor body 81a and a plurality of distribution pipes 81b branching from the body of the distributor 81a.

(4-2-1) Distributor body 81a

The distributor body 81a is arranged in the pipe receiving space S between the first lateral end portion 32a and the second lateral end portion 32b of the internal heat exchanger 32. The distributor body 81a is formed in tubular form with a bottom and a vertically extending axis. Distribution pipes 81b are connected to an upper end surface of distributor body 81a.

Figure 6 schematically shows a positional relationship of the distributor 81 with respect to the height direction of the indoor heat exchanger 32 in a state of use. In Figure 6, the upper part of the distributor body 81a (i.e. a connection to the distribution pipes 81b) is located above the center of the height of the indoor heat exchanger 32 with respect to the height direction of the exchanger heat exchanger 32 in a front view of FIG. 6. The body of the distributor 81a is oriented towards the second lateral end portion 32b of the indoor heat exchanger 32 with the connection to the distribution pipes 81b oriented vertically upwards.

As shown in Figures 1 and 6, during a cooling operation, the distributor body 81a allows the refrigerant flowing out of the liquid transmission line 82 to divide and flow into the respective distribution lines 81b. On the other hand, during a heating operation, the distributor body 81a allows the refrigerant flowing out of the respective distribution pipes 81b to join.

(4-2-2) Distribution pipes 81b

The distribution pipes 81b are arranged between the body of the distributor 81a and the second lateral end portion 32b of the internal heat exchanger 32. Each of the distribution pipes 81b is configured with a capillary tube, the flow channel of which is smaller diameter than that of the distributor body 81a.

As shown in Figure 6, the connection of the distributor body 81a to the distribution pipes 81b is located above the center of the height of the indoor heat exchanger 32; In the present embodiment, taken as an example, this connection is located slightly higher than the height position of a seventh row heat transfer tube down from the top of the indoor heat exchanger 32.

On the other hand, the connection of the distributor body 81a to the distribution pipes 81b is oriented vertically upwards. For these reasons, the distribution pipes 81b connected to the respective heat transfer pipes of the upper row to the sixth row of the indoor heat exchanger 32 are located higher than the connection of the distributor body 81a to the distribution pipes 81b. .

On the other hand, the distribution pipes 81b connected to the respective heat transfer pipes of the seventh to sixteenth row of the indoor heat exchanger 32 are located lower than the connection of the distributor body 81a to the distribution pipes 81b.

Therefore, during cooling, the liquid refrigerant flowing through the distribution pipes 81b connected to the respective heat transfer pipes of the upper row to the sixth row of the indoor heat exchanger 32 flows against gravity, and The liquid refrigerant flowing through the distribution pipes 81b connected to the respective heat transfer pipes from the seventh to the sixteenth row of the indoor heat exchanger 32 flow according to the force of gravity.

On the other hand, during heating, the liquid refrigerant flowing through the distribution pipes 81b connected to the respective heat transfer pipes of the topmost row to the sixth row of the indoor heat exchanger 32 flows according to the force of gravity, and the liquid refrigerant flowing through the distribution pipes 81b connected to the respective heat transfer pipes from the seventh to the sixteenth row of the indoor heat exchanger 32 flows against gravity.

(4-2-3) Liquid Transmission Line 82

The liquid transmission line 82 connects the distributor body 81a to the liquid side connection pipe 6 through a substantially U-shaped bent transmission portion 83, which extends vertically downward from the distributor body 81a , and extends upward to the liquid side connection pipe 6.

(5) Installation position of coolant temperature sensor 183

Next, the coolant temperature sensor 183 for detecting a temperature of the coolant flowing through the indoor heat exchanger 32 is mounted on the indoor heat exchanger 32.

Since heat transfer fins are present between the first side end portion 32a and the second side end portion 32b of the indoor heat exchanger 32, the coolant temperature sensor 183 is mounted on one of a plurality of sub-portions which is project laterally from the first lateral end portion 32a or the second lateral end portion 32b of the indoor heat exchanger 32.

(5-1) Detail of mounting position

Fig. 7 is a plan view of a heat transfer tube of the indoor heat exchanger 32. In Figures 6 and 7, the indoor heat exchanger 32 has eighteen heat transfer tubes (hereinafter referred to as trajectories of refrigerant P) that travels back and forth between the first side end portion 32a and the second side end portion 32b.

Each of the refrigerant paths P is configured with a plurality of straight pipes 323, a plurality of bends 325, a first U-portion 327, and a second U-portion 329.

In the present embodiment, the height direction of the indoor heat exchanger 32 in the used state is oriented in the up and down direction. The refrigerant paths P as shown in Fig. 7 are arranged in the up and down direction of the indoor heat exchanger 32.

To form the first U-shaped portion 327 of the indoor heat exchanger 32, two straight pipes are joined together with a U-shaped pipe. On the other hand, to form the second U-shaped portion 329, a straight pipe is flexed U-shaped.

Since the refrigerant path P as shown in Fig. 7 travels back and forth between the first side end portion 32a and the second side end portion 32b as described above, the first U-portion 327 is located on the first end portion side 32a and the second U-portion 329 is located on the second side end portion 32b.

For a configuration of the refrigerant path P as described above, it is desirable that a mounting position of the refrigerant temperature sensor 183 to a path of the refrigerant P be located above the height center of the indoor heat exchanger 32 in the state of use or the body of the distributor 81a.

For example, in air conditioning apparatus 10, when compressor 12 operates at a lower number of compressor rotations at the output of a minimum heating capacity of less than 45% of its nominal heating capacity, accumulation of liquid tends not to occur in the coolant paths P higher than the body of the distributor 81a, while the accumulation of liquid tends to occur in the coolant paths P lower than the body of the distributor 81a.

This would be caused by the liquid in the refrigerant paths P lower than the distributor body 81a, which cannot rise to the distributor body 81a under the influence of gravity, since the amount of circulating refrigerant is reduced.

However, even when the compressor 12 operates at a lower number of compressor rotations at the output of the minimum heating capacity to reduce a quantity of circulating refrigerant, the accumulation of liquid does not occur above the center in height of the exchanger heat exchanger 32 or distributor body 81a. Therefore, the coolant temperature sensor 183 mounted in the region described above can detect an accurate saturation temperature.

For a more specific mounting position, the coolant temperature sensor 183 is mounted on a coolant path P, out of the plurality of coolant paths P, in a range that occupies 30% of all paths down from the uppermost coolant path P of the indoor heat exchanger 32.

For example, it is preferable to mount it on one of the coolant paths of the topmost row to the sixth row P in an indoor heat exchanger 32 having eighteen paths in total, such as that of the present embodiment. In the present embodiment, as shown in FIG. 6, the coolant temperature sensor 183 is mounted in a second row of the second U-portion 329.

The coolant temperature sensor 183 is mounted on the second U-portion 329 of the indoor heat exchanger 32 because the fins between the first side-end portion 32a and the second side-end portion 32b make it difficult to allocate space efficient mounting. Therefore, it is unavoidable to mount it in the first portion in U 327 or in the second portion in U 329.

However, when subcooling occurs throughout the system, to prevent a saturation temperature from failing to be detected, it is preferable to mount not to the first U-portion 327 as a liquid side, but to the second U-portion 329 as one end on the gas side with respect to the flow of the refrigerant flowing through the path of the refrigerant P.

It should be noted that the coolant temperature sensor 183 may be mounted in the coolant path of the uppermost row P of the indoor heat exchanger 32.

(5-2) Effect of mounting position of coolant temperature sensor 183

FIG. 8 is a graph showing temperature distributions in indoor heat exchanger 32 during operation at minimum heating capacity. Figure 8 shows a value detected by the coolant temperature sensor 183 in ordinates and the position of the coolant paths in abscissa. The number of positions of the coolant paths P of the indoor heat exchanger 32 starts at 1 from the coolant path of the top row P, and the number of positions increases sequentially for the bottom coolant paths P.

As shown in Figure 8, in the case where the coolant temperature sensor 183 is placed on the liquid side of a coolant path P, as the number of positions of the coolant paths increases, the values they are more different from the saturation temperature, except for the refrigerant path in the top row P (graph A).

In contrast to this, in the case where the coolant temperature sensor 183 is placed in an intermediate position of a coolant path P, the values in the coolant paths of the topmost row to the eighth row P are more near the saturation temperature, and the values in the refrigerant paths P below these refrigerant paths are more different from the saturation temperature (graph •).

On the other hand, in the case where the refrigerant temperature sensor 183 is placed on the gas side of a refrigerant path P, the values in the refrigerant paths P higher than the thirteenth row P are closer to the temperature saturation temperature, and the values in the refrigerant routes P below these refrigerant routes are more different from the saturation temperature (graph ■).

The results described above have shown that "it is desirable that a mounting position of the coolant temperature sensor 183 in a coolant path P be above the center of height of the indoor heat exchanger 32 in use or of the body of the distributor 81a "and" it is preferable to mount it not on the liquid side but on the end side of the gas side with respect to the flow of the coolant flowing through the path of the coolant P ".

(6) Features

(6-1)

Even when compressor 12 operates at a smaller number of compressor rotations to produce the minimum heating capacity to reduce an amount of refrigerant circulation, as liquid accumulation does not occur above the height center of the indoor heat exchanger 32 or the body distributor 81a, the air conditioning apparatus 10 allows the coolant temperature sensor 183 mounted in the region described above to detect an accurate saturation temperature. Accordingly, the likelihood of subcooling control impediment is eliminated, whereby the control of opening of an electric valve in the conventional manner need not be performed solely for the removal of liquid accumulation. Of course, no pressure sensor is needed.

(6-2)

Since the coolant temperature sensor 183 is mounted on a coolant path P, out of the plurality of coolant paths P, in an area that occupies 30% of all paths from the coolant path of the most row Higher P, the air conditioning apparatus 10 enables safer detection of an accurate saturation temperature.

(6-3)

In the case where the coolant temperature sensor 183 is mounted on the coolant path of the topmost row P of the plurality of coolant paths P, the air conditioning apparatus 10 allows for a more reliable detection of a temperature of accurate saturation.

(6-4)

Since the coolant temperature sensor 183 is mounted not on the first side end portion 32a of the indoor heat exchanger 32 as the liquid side, but on the second side end portion 32b of the indoor heat exchanger 32 as the side of the gas, the end side with respect to the flow of the refrigerant flowing through the path of the refrigerant P, the air conditioning apparatus 10 prevents detection of a saturation temperature from failing when subcooling occurs throughout the system.

(6-5)

With compressor 12 having a range sufficient to allow "a minimum heating operating state in which compressor 12 continuously operates for 30 seconds or more at a smaller number of compressor rotations to produce a minimum heating capacity of less than 45% of a nominal heating capacity thereof ", even if compressor 12 operates at a lower number of compressor rotations in the course of events to produce a minimum heating capacity to reduce the amount of refrigerant circulation, such as accumulation of liquid is not produced above the height center of the indoor heat exchanger 32 or the distributor body 81a, the coolant temperature sensor 183 mounted in the region described above can detect an accurate saturation temperature, the air conditioning apparatus air 10 allows the coolant temperature sensor 183 to detect a temperature of accurate saturation.

(7) Other achievements

In the above embodiment, for the mounting position of the coolant temperature sensor 183, the indoor heat exchanger used in the indoor unit 20 mounted on the ceiling has been described as an example. The idea of the mounting position of the refrigerant temperature sensor 183 can be applied to indoor heat exchangers used in indoor units other than the indoor unit described above. For example, floor model indoor units, two-way indoor units, ceiling-suspended indoor units, ducted indoor units, roof-mounted one-way indoor units will be provided. Here, as typical examples, a floor model indoor unit and a two-way indoor unit will be described.

(7-1) 132 indoor heat exchanger used in a floor model indoor unit

Figure 9 schematically shows, for an indoor heat exchanger 132 used in a floor model indoor unit, a positional relationship of the distributor 81 with respect to the height direction of the indoor heat exchanger 132 in use state.

As shown in Fig. 9, the indoor heat exchanger 132 in use state assumes an inclined orientation, and in this indoor heat exchanger, ten refrigerant paths P are arranged from top to bottom. The intervals between the paths of refrigerant P are not equal to each other.

The connection of the distributor body 81a to the distribution pipes 81b is slightly lower than the height position of a sixth row P refrigerant path down from the top of the indoor heat exchanger 132, and corresponds to the center height of the indoor heat exchanger 132.

On the other hand, the connection of the distributor body 81a to the distribution pipes 81b is oriented vertically upwards. For these reasons, the distribution pipes 81b connected to the respective refrigerant paths P of the upper row to the sixth row of the indoor heat exchanger 132 are located higher than the connection of the distributor body 81a to the distribution pipes 81b.

On the other hand, the distribution pipes 81b connected to the respective refrigerant paths P of the seventh to tenth row of the indoor heat exchanger 132 are located lower than the connection of the distributor body 81a to the distribution pipes 81b.

Therefore, during cooling, the liquid refrigerant flowing through the distribution pipes 81b connected to the respective refrigerant paths P of the top row to the sixth row of the indoor heat exchanger 132 flows against gravity, and the Liquid refrigerant flowing through the distribution pipes 81b connected to the respective heat transfer pipes from the seventh to the tenth row of the indoor heat exchanger 132 flow according to the force of gravity.

On the other hand, during heating, the liquid coolant flowing through the distribution pipes 81b connected to the respective coolant paths P of the topmost row to the sixth row of the indoor heat exchanger 132 flows according to the force of gravity, and the liquid refrigerant flowing through the distribution pipes 81b connected to the respective refrigerant paths from the seventh to the tenth row of the indoor heat exchanger 132 flows against gravity.

To detect an accurate saturation temperature even if liquid build-up occurs in an operating state with circulating amounts in a low range, as shown in Figure 9, it is desirable that a mounting position of the coolant temperature sensor 183 in a path of coolant P is above the center of height of the indoor heat exchanger 132 in use or of the distributor body 81a in the same way as the internal heat exchanger of the embodiment described above. Furthermore, it is preferable to mount it not on the liquid side but on the end side of the gas side with respect to the flow of the refrigerant flowing through the path of the refrigerant P.

FIG. 10 is a graph showing temperature distributions in indoor heat exchanger 132 during operation at minimum heating capacity. Figure 10 shows a value detected by the coolant temperature sensor 183 in ordinates and the position of the coolant paths P in abscissa. The number of positions of the coolant paths P of the indoor heat exchanger 32 starts at 1 from the coolant path of the top row P, and the number of positions increases sequentially for the bottom coolant paths P.

As shown in Figure 10, in the case where the coolant temperature sensor 183 is placed on the liquid side of a coolant path P, as the number of positions of the coolant paths increases, the values they are more different from the saturation temperature, except for the refrigerant trajectories from the top row to the fifth row P (graph A).

In contrast to this, in the case where the coolant temperature sensor 183 is placed in an intermediate position of a coolant path P, the values in the coolant paths of the topmost row to the seventh row P are more near the saturation temperature, and the values in the refrigerant paths P below these refrigerant paths are more different from the saturation temperature (graph •).

On the other hand, in the case where the coolant temperature sensor 183 is placed on the gas side of a coolant path P, the values in the coolant paths of the topmost row to the eighth row P are more near the saturation temperature, and only the values in the coolant paths of the ninth row and the lowest, tenth row P are more different from the saturation temperature (graph ■).

The results described above have demonstrated that "it is desirable that a mounting position of the coolant temperature sensor 183 in a path of coolant P be above the center of height of the indoor heat exchanger 132 in use or of the body of the distributor 81a "and" it is preferable to mount it not on the liquid side but on the end side of the gas side with respect to the flow of the coolant flowing through the path of the coolant P ".

(7-2) 232 indoor heat exchanger used in two-way indoor unit

Fig. 11 schematically shows, for an indoor heat exchanger 232 used in a two-way indoor unit, a positional relationship of the distributor 81 with respect to the height direction of the indoor heat exchanger 232 in use state.

As shown in Figure 11, the indoor heat exchanger 232 includes two heat exchangers facing each other, and in each of these heat exchangers, seven refrigerant paths P are arranged from top to bottom.

The connection of the distributor body 81a to the distribution pipes 81b is slightly higher than the height position of a fourth row P refrigerant path down from the top of the indoor heat exchanger 232, and almost corresponds to the height center of indoor heat exchanger 232.

On the other hand, the connection of the distributor body 81a to the distribution pipes 81b is oriented vertically upwards. For these reasons, the distribution pipes 81b connected to the respective refrigerant paths P of the upper row to the third row of the indoor heat exchanger 232 are located higher than the connection of the distributor body 81a to the distribution pipes 81b.

On the other hand, the distribution pipes 81b connected to the respective refrigerant paths P of the fourth to seventh row of the indoor heat exchanger 232 are located lower than the connection of the distributor body 81a to the distribution pipes 81b.

Therefore, during cooling, the liquid refrigerant flowing through the distribution pipes 81b connected to the respective refrigerant paths P of the topmost row to the third row of the indoor heat exchanger 232 flows against gravity, and the liquid refrigerant flowing through the distribution pipes 81b connected to the respective refrigerant paths P from the fourth to the seventh rows of the indoor heat exchanger 232 flow according to the force of gravity.

On the other hand, during heating, the liquid coolant flowing through the distribution pipes 81b connected to the respective coolant paths P from the topmost row to the third row of the indoor heat exchanger 232 flows according to the force of gravity, and the liquid coolant flowing through the distribution pipes 81b connected to the respective coolant paths from the fourth to the seventh row of the indoor heat exchanger 232 flows against gravity.

To detect an accurate saturation temperature even if liquid build-up occurs in an operating state with circulating amounts in a low range, as shown in Figure 11, a mounting position of the coolant temperature sensor 183 in a path Coolant P is located above the center of height of the indoor heat exchanger 232 in use or the distributor body 81a in the same manner as the indoor heat exchanger of the previously described embodiment. Also, the coolant temperature sensor 183 is mounted not on the liquid side, but on the end side of the gas side with respect to the flow of the coolant flowing through the path of the coolant P.

Industrial applicability

The present invention is useful for an air conditioning apparatus to be able to spontaneously implement a minimal heating operating state.

List of! reference signs

10 Air conditioning apparatus

32 Indoor heat exchanger

81 Distributor

81st Distributor Body

81b Distribution piping

183 Temperature sensor

Appointment list

Patent bibliography

Patent Bibliography 1: JP-A-H5-280808

Claims (5)

1. An air conditioning apparatus that includes an indoor heat exchanger (32) and is configured to allow the indoor heat exchanger (32) to function as a radiator for refrigerant and perform a heating operation, comprising: a distributor (81) that includes: a distributor body (81a) placed in the vicinity of a coolant outlet of the indoor heat exchanger (32) that functions as a radiator; and a plurality of distribution pipes (81b) branching from the distributor body (81a) and each connected to one of a plurality of refrigerant paths (P) formed in the indoor heat exchanger (32); and a temperature sensor (183) configured to detect a saturation temperature of the refrigerant flowing through the indoor heat exchanger (32), in which the temperature sensor (183) is mounted on a center in height of the interior heat exchanger (32) in use or the distributor body (81a), characterized by that in a particular path, among the plurality of refrigerant paths (P), in which the temperature sensor (183) is mounted, the temperature sensor (183) is mounted on one end of the gas side of the path particular, with respect to a flow of refrigerant flowing through the particular path. 2. The air conditioning apparatus according to claim 1, wherein: the indoor heat exchanger (32) has a first side end portion (32a) and a second side end portion (32b); each of the plurality of refrigerant paths (P) travels back and forth between the first side end portion (32a) and the second side end portion (32b) to form a first U-shaped portion (327) in the first lateral end portion (32a) and a second U-shaped portion (329) in the second lateral end portion (32b); the plurality of distribution pipes (81b) are connected to the plurality of refrigerant paths (P) in the second lateral end portion (32b); and the temperature sensor (183) is mounted on the second U-shaped portion (329). 3. The air conditioning apparatus according to claim 1 or 2, wherein: when a height direction of the indoor heat exchanger in use state is oriented up and down, the plurality of refrigerant paths (P) are arranged in the up and down direction of the indoor heat exchanger; and The temperature sensor 183 is mounted in one path, between the plurality of refrigerant paths (P), in a range that occupies 30% of all refrigerant paths from the topmost row refrigerant path. 4. The air conditioning apparatus according to claim 3, wherein the temperature sensor (183) is mounted in the coolant path of the uppermost row among the plurality of coolant paths (P). The air conditioning apparatus according to any one of claims 1 to 4, further comprising: a compressor (12) configured to compress low-pressure refrigerant and discharge a high-pressure refrigerant that must flow through the indoor heat exchanger; and a controller (800), in which: The controller is configured to control the compressor to run continuously for 30 seconds or more at a smaller number of compressor rotations to produce a minimum heating capacity less than 45% of the nominal heating capacity of the compressor.