DE112021008363T5 - Distributor, heat exchanger, and heat pump device - Google Patents

Abstract

A manifold, a heat exchanger, and a heat pump device each include an outer wall portion having a cylindrical shape and extending in a transverse direction, and a plurality of cylindrical portions extending in the transverse direction, the plurality of cylindrical portions being provided in the outer wall portion or in a hollow portion within the outer wall portion and each having a flow channel having a circular cross section within the cylindrical portion. The plurality of cylindrical portions are provided parallel to each other. The outer wall portion has a plurality of communication openings formed in an upper or lower part of the outer wall portion and spaced from each other in the transverse direction. Each of the plurality of cylindrical portions has a plurality of openings provided in the cylindrical portion and spaced from each other in the transverse direction.

Description

TECHNICAL AREA

The present invention relates to a distributor that distributes refrigerant to a plurality of heat transfer tubes, a heat exchanger having this distributor, and a heat pump device having this distributor.

State of the art

A manifold has a double-tube configuration of an outer tube and an inner tube (see, for example, Patent Document 1). In such a manifold, the inner tube is provided with a refrigerant outlet, also called an opening. The refrigerant flowing into a flow channel inside the inner tube in the manifold is discharged into a space between the inner tube and the outer tube via a plurality of the refrigerant outlets, and flows from this space into a plurality of heat transfer tubes.

List of quotes

Patent literature

Patent Document 1: Japanese Patent Application Laid-Open JP 6 523 858 A

SUMMARY OF THE INVENTION

Technical problem

In Patent Document 1, the refrigerant is discharged through the openings provided in the inner tube so that the refrigerant is evenly distributed. However, in an arrangement such as the distributor of Patent Document 1 in which only one inner tube is provided inside an outer tube, all of the refrigerant distributed to the many heat transfer tubes is passed through one inner tube, so that a pressure loss of the refrigerant in the distributor undesirably increases.

The present invention has been made to solve the above problem and aims to provide a distributor, a heat exchanger and a heat pump device each configured to eliminate or reduce an increase in pressure loss while maintaining uniform distribution through openings.

Troubleshooting

A manifold according to an embodiment of the present invention includes an outer wall portion having a cylindrical shape and extending in a transverse direction, and a plurality of cylindrical portions extending in the transverse direction, the plurality of cylindrical portions being provided in the outer wall portion or in a hollow portion within the outer wall portion and each having a flow channel having a circular cross section within the cylindrical portion. The plurality of cylindrical portions are provided in parallel to each other. The outer wall portion has a plurality of communication openings formed in an upper or lower part of the outer wall portion and spaced from each other in the transverse direction. Each of the plurality of cylindrical portions has a plurality of openings provided in the cylindrical portion and spaced from each other in the transverse direction.

Further, a heat exchanger according to an embodiment of the present invention includes a plurality of transversely arranged heat transfer tubes extending in an up-down direction, and two headers provided at the two respective ends of the plurality of heat transfer tubes and each distributing and merging refrigerant. At least one of the two headers includes the above-mentioned distributor. Some of the plurality of heat transfer tubes are connected to the plurality of connection holes of the distributor.

Furthermore, a heat pump device according to an embodiment of the present invention includes a refrigerant circuit with the above-mentioned heat exchangers and a compressor designed to compress the refrigerant.

Advantageous effects of the invention

Each of the distributor, the heat exchanger, and the heat pump device according to an embodiment of the present invention includes the plurality of cylindrical portions each having a flow channel with a circular cross section within the cylindrical portion, and the plurality of cylindrical portions are provided parallel to each other in the outer wall portion or the hollow portion. This results in refrigerant being distributed into a plurality of the flow channels. This makes it possible to make the flow channel area per cylindrical portion smaller than in a configuration in which refrigerants are distributed to the plurality of heat transfer tubes via only one inner tube. This makes it possible to provide a distributor, a heat exchanger, and a heat pump device each configured to eliminate or reduce an increase in pressure loss while simultaneously Maintain uniform distribution through openings.

BRIEF DESCRIPTION OF THE DRAWINGS

• 1 is a cross-sectional view showing an example of a heat exchanger with a distributor according to Embodiment 1;
• 2 is a cross-sectional view showing a cross section along the line AA of the 1 shown distributor;
• 3 is a cross-sectional view showing an example of a 1 shown final distributor;
• 4 is a refrigerant circuit diagram of a heat pump device with the 1 shown heat exchanger;
• 5 is a schematic view showing the position of an opening in a cylindrical portion of a distributor according to Embodiment 2;
• 6 is a diagram showing the effect on the liquid level angle of the 5 shown refrigerant about the quality of the refrigerant;
• 7 is a schematic view showing a first modification of the cylindrical portions of the distributor according to Embodiment 2;
• 8th is a cross-sectional view showing an example of a distributor according to Embodiment 3;
• 9 is a schematic view showing a second modification of the distributor according to Embodiment 3;
• 10 is a cross-sectional view showing an example of a distributor according to Embodiment 4;
• 11 is a cross-sectional view showing an example of a distributor according to Embodiment 5;
• 12 is a cross-sectional view showing a cross section along the line BB of the 11 shown distributor;
• 13 is a cross-sectional view showing a cross section along the line CC of the 11 shown distributor, and
• 14 is a cross-sectional view showing an example of a distributor according to Embodiment 6.

EMBODIMENTS OF THE INVENTION

Embodiment 1

1 is a cross-sectional view showing an example of a heat exchanger 100 having a manifold 20 according to Embodiment 1. 2 is a cross-sectional view showing a cross section along the line AA of the 1 shown distributor 20. 3 is a cross-sectional view showing an example of the 1 A configuration of the heat exchanger 100 is shown with reference to the 1 to 3 described.

As in 1 As shown, the heat exchanger 100 includes a plurality of heat transfer tubes 1, first and second headers 2a and 2b arranged at the two respective ends of the plurality of heat transfer tubes 1, and two tubes 3a and 3b serving as an inlet and an outlet through which refrigerant flows into and out of the heat exchanger 100. In addition, the heat exchanger 100 includes a plurality of fins, but these are not shown. In the following description, the first header 2a and the second header 2b are sometimes referred to simply as "headers" if they are not particularly distinguished from each other. Each of the headers has a header outer wall having a cylindrical shape. In 1 The outline arrows and the solid arrows in the headers indicate directions in which refrigerant flows.

Three mutually orthogonal directions are defined here as a first direction D1, a second direction D2 and a third direction D3 (see 2 ), wherein the first direction D1 is defined as a longitudinal direction parallel to the longitudinal sides of the headers, ie as an axial direction. In the heat exchanger 100, the plurality of heat transfer tubes 1 are arranged in the first direction D1 and regularly spaced from each other, and each of the plurality of heat transfer tubes 1 extends in the second direction D2.

In the following description, directional terms (such as "top", "bottom", "right", "left", "front" and "back") are used to facilitate understanding, but these are for illustrative purposes only and are not intended to limit the present invention. Unless clearly stated otherwise, these terms refer to directions viewed from the front of the heat exchanger 100 as shown in 1 Furthermore, in the following description, for the sake of simplicity, the first direction D1, which is the longitudinal direction of the headers, is defined as the transverse direction across the heat exchanger 100, and the second direction D2, which is the longitudinal direction is parallel to the longitudinal sides of the plurality of heat transfer tubes 1, is defined as the up-down direction from the top of the heat exchanger 100 downward.

The heat transfer tubes 1 are, for example, flat tubes. The plurality of heat transfer tubes 1 have upper ends 1e inserted into the header outer wall of the first header 2a, and the plurality of heat transfer tubes 1 have lower ends 1e inserted into the header outer wall of the second header 2b.

In a lower portion of the header outer wall of the first header 2a, a plurality of communication holes 21o into which the upper ends 1e of the heat transfer tubes 1 are inserted are formed and spaced apart from each other in the transverse direction. Further, in an upper portion of the header outer wall of the second header 2b, a plurality of communication holes 21o into which the lower ends 1e of the heat transfer tubes 1 are inserted are formed and spaced apart from each other in the transverse direction. A space through which refrigerant flows is defined within each of the first and second headers 2a and 2b. The space within the first header 2a and the space within the second header 2b communicate with each other via the plurality of heat transfer tubes 1. The first header 2a and the second header 2b each distribute refrigerant to the plurality of heat transfer tubes 1 and each cause refrigerant flows from the plurality of heat transfer tubes 1 to merge with each other. Furthermore, in the 1 example shown, a pipe 3a is provided at a left end of the second header 2b, and a pipe 3b is provided at a right end of the second header 2b.

Each of the plurality of fins (not shown) is, for example, a wave-shaped fin. Each fin is arranged between adjacent heat transfer tubes 1 and connected to the surfaces of the two heat transfer tubes 1. The fins are intended to transfer heat to the heat transfer tubes 1 to improve the efficiency of heat exchange between air and refrigerant.

For example, the plurality of heat transfer tubes 1, the plurality of fins (not shown), the first header 2a and the second header 2b may all be made of aluminum. In this case, they are connected to each other by, for example, brazing.

At least one of the first and second headers 2a and 2b includes a distributor 20. Further, in a case where a distributor 20 is provided in a part of one of the first and second headers 2a and 2b in the longitudinal direction, the header not provided with a distributor 20 is provided with a divider 4 which divides the space inside the header into a plurality of spaces. In the 1 In the example shown, the right half of the first header 2a in the longitudinal direction (first direction D1) serves as a distributor 20, and the second header 2b, which has no distributor 20, has a divider 4 which divides the space within the second header 2b into a left space and a right space.

The design of the distributor 20 is described with reference to the 1 to 3 The distributor 20 includes an outer wall portion 21 and cylindrical portions 22. The outer wall portion 21 has a cylindrical shape and has a hollow portion 21a. The cylindrical portions 22 are provided in the hollow portion 21a, extend in the transverse direction (first direction D1) and each have a flow channel 22p inside them. The outer wall portion 21 of the distributor 20 is the right half of the header outer wall of the first header 2a. A plurality of openings 22o are provided in the cylindrical portion 22, which are regularly spaced from one another in a flow channel in the axial direction, ie in the first direction D1. In the 1 In the example shown, eighteen heat transfer tubes 1 are connected to the outer wall portion 21 of the distributor 20, and the cylindrical portion 22 has seven openings 22o in the transverse direction. The cylindrical portion 22, which is in 1 extending in the transverse direction, includes a plurality of cylindrical regions 22, as shown in 2 and the plurality of cylindrical portions 22 are provided parallel to each other in the hollow portion 21a. The openings 22o have, for example, circular shapes. Alternatively, the openings 22o may also be slit-shaped.

As in 2 As shown, the flow channel 22p has a circular cross section in a cross section perpendicular to an axial direction parallel to the axis of the cylindrical portion 22. In the 2 In the example shown, the cylindrical portion 22 has a circular cylindrical shape. In the following description, the part of the cylindrical portion 22 that is higher than a line passing through the center C1 of the cylindrical portion 22 and parallel to the third direction D3 (ie, a front-back direction from the front of the heat exchanger 100 to the back) is sometimes referred to as an "upper cylindrical portion", and the part of the cylindrical portion 22 that is lower than the line is sometimes referred to as a "lower cylindrical portion".

In the cross section perpendicular to the axial direction of the cylindrical portion 22, the openings 22o can be provided in any positions. For example, the distance between the ends 1e of the heat transfer tubes 1 and the openings 22o is shortened if the openings 22o are provided in one of the upper and lower cylindrical portions which is closer than the other to the connecting openings 21o of the outer wall portion 21 into which the heat transfer tubes 1 are inserted. In the 2 In the example shown, the communication openings 21o are formed in a lower part of the outer wall portion 21 of the distributor 20, the openings 22o are provided in the lower cylindrical portion of each cylindrical portion 22.

Furthermore, the distributor 20 includes an end divider 23 provided at one end of the outer wall portion 21 in the first direction D1, so that the end divider 23 closes a space which is further inside than the outer wall portion 21 and further outside than one of the many flow channels 22p. In the 1 In the example shown, the end divider 23 is provided at a left end of the distributor 20 in the transverse direction (first direction D1). As in 3 As shown, the end divider 23 may, for example, be a plate-shaped member arranged such that the plate-shaped member extends along a plane perpendicular to the first direction D1 and is provided with substantially circular openings 23a connected to the flow channels 22p. The number of openings 23a provided in the end divider 23 is equal to the number of flow channels 22p.

As in 1 As shown, a right end surface of each cylindrical portion 22 is connected to an inner surface of a right end of the first header 2a, and a right end of the hollow portion 21a of the manifold 20 is closed by the right end of the first header 2a. Further, a left end surface of each cylindrical portion 22 is connected to an end of the corresponding opening 23a on a right side surface of the end divider 23, and a left end of the hollow portion 21a, which is further outward than the plural cylindrical portions 22, is closed by the end divider 23.

The openings 23a of the end divider 23 cause a left space within the first header 2a to communicate with the plurality of flow channels 22p in the manifold 20. The aforementioned openings 22o cause the flow channels 22p to communicate with a space in the hollow portion 21a located outside the cylindrical portions 22. The plurality of heat transfer tubes 1 connected to the outer wall portion 21 of the manifold 20 are connected to a part of the second header 2b located further to the right than the divider 4, and cause the space in the hollow portion 21a of the manifold 20 located outside the cylindrical portions 22 to communicate with a right space within the second header 2b. The divider 4 is designed such that the divider 4 prevents refrigerant flowing via the plurality of heat transfer tubes 1 from the distributor 20 of the first header 2a into the right space in the second header 2b from being mixed with refrigerant in the left space in the second header 2b, i.e. refrigerant that is still to flow into the first header 2a.

In the following, the operation of the heat exchanger 100 is described with reference to 1 described. Refrigerant flows from the pipe 3a into the left space in the second header 2b, is distributed to a plurality of heat transfer tubes 1 connected to this left space, exchanges heat with air while rising through these heat transfer tubes 1, and flows into the left space in the first header 2a. The refrigerant flowing into the left space in the first header 2a flows into the multiple flow channels 22p of the header 20 via the openings 23a of the end header 23. The refrigerant flowing into the flow channels 22p via the openings 23a is discharged into the space in the hollow portion 21a located outside the cylindrical portions 22 as it flows through the flow channels 22p to the right via the multiple openings 22o provided in the cylindrical portions 22 and spaced apart from one another, and flows into a plurality of heat transfer tubes 1 connected to the header 20. The refrigerant flowing from the header 20 into these heat transfer tubes 1 exchanges heat with air as it passes through the heat transfer tubes 1, flows into the right space in the second header 2b, and then flows out of the heat exchanger 100 through the tube 3b. In the heat exchanger 100, the flow of refrigerant is not limited to one direction, but the refrigerant may also flow in the opposite direction. That is, the refrigerant flowing into the heat exchanger 100 via the pipe 3b may flow in a direction in which the refrigerant flows out via the pipe 3a after heat exchange in the region of the plurality of heat transfer tubes 1.

Although in the 1 the distributor 20 is provided in the right half of the first head piece 2a in the first direction D1, the distributor 20 can be provided at any location or in any area of the first head piece 2a. For example, the distributor 20 can be provided in the entire area of the first head piece 2a in the first direction D1. Although in the example shown in 1 shown example, the distributor 20 only in the first head piece 2a, the upper ren of the two headers 2a and 2b, a distributor 20 may also be provided in the second header 2b, or the distributor 20 may be provided in both the first header 2a and the second header 2b. Furthermore, the location in one header where the divider 4 is provided may be determined according to the location and area in the other header where the distributor 20 is provided. Furthermore, the locations in the heat exchanger 100 where the tubes 3a and 3b are provided are not limited to the locations shown in 1 shown. Further, the number of openings 22o in each cylindrical portion 22 and a distance between the openings 22o are not limited to the above case.

4 is a refrigerant circuit diagram of a heat pump device 10 with the 1 shown heat exchanger 100. In 4 the outline arrows indicate directions in which refrigerant flows. The heat pump device 10 includes a refrigerant circuit 10a configured to transfer heat by utilizing the latent heat of evaporation and condensation of the refrigerant. Examples of the heat pump device 10 include an air conditioner configured to heat the interior of a room with an evaporator installed outdoors and a condenser installed indoors, and a hot water supply system configured to make water heated by a condenser warm or hot.

The following describes a case in which, as in 4 shown, the above heat exchanger 100 is provided in the refrigerant circuit 10a so that the heat exchanger 100 serves as an evaporator in the heating mode of the heat pump device 10. Alternatively, the heat exchanger 100 can be provided in the refrigerant circuit 10a so that the heat exchanger 100 serves as a condenser in the heating mode of the heat pump device 10.

The refrigerant circuit 10a is formed by a compressor 11, a heat exchanger 13, a pressure reducer 14 and the heat exchanger 100, which are connected to each other by refrigerant pipes. The compressor 11 sucks in low-pressure gas refrigerant, compresses the low-pressure gas refrigerant to high-pressure gas refrigerant, releases the high-pressure gas refrigerant and circulates the high-pressure gas refrigerant through the refrigerant circuit 10a. The heat exchanger 13 and the heat exchanger 100 effect heat exchange between the refrigerant and the air. The pressure reducer 14 is, for example, an expansion valve and expands and decompresses the refrigerant.

The compressor 11 may be an inverter compressor or another device whose performance, i.e. the delivery rate per unit time, is controlled by changing the operating frequency. When the compressor 11 is configured in this way, it is possible to adjust the frequency of the compressor 11 so that the amount of refrigerant circulating through the refrigerant circuit 10a and the amount of heat moving through the refrigerant circuit are varied according to a load or other conditions. Furthermore, the use of a valve as a pressure reducer 14, the degree of opening of which is continuously variable, makes it possible to change the pressure of the refrigerant circulating through the refrigerant circuit 10a.

In the 1 In the example shown, the refrigerant circuit 10a further includes a flow switching device 12. The flow switching device 12 is configured to switch the flow channels of the refrigerant discharged from the compressor 11, and is, for example, a four-way valve. Note that the configuration of the refrigerant circuit 10a is not limited to the above configuration. For example, the flow switching device 12 may be omitted.

The flow switching device 12 enables switching between cooling and heating operations. In the heating operation, the refrigerant flowing out of the compressor 11 flows through the heat exchanger 13, the pressure reducer 14, and the heat exchanger 100 in sequence and then returns to the compressor 11. Meanwhile, in the cooling operation, the refrigerant flowing out of the compressor 11 flows through the heat exchanger 100, the pressure reducer 14, and the heat exchanger 13 in sequence and then returns to the compressor 11. One of the heat exchangers 13 and 100, which serves as a condenser, converts high-pressure gaseous refrigerant into liquid refrigerant by causing the high-pressure gaseous refrigerant to release heat to the outside air. One of the heat exchangers 13 and 100, which serves as an evaporator, evaporates liquid refrigerant contained in low-pressure refrigerant into gaseous refrigerant by causing the liquid refrigerant to release heat from the outside air.

As mentioned above, the distributor 20 according to Embodiment 1 includes an outer wall portion 21 having a cylindrical shape extending in the transverse direction (first direction D1) and having a hollow portion 21a and a plurality of cylindrical portions 22 extending in the transverse direction provided in the hollow portion 21a and each having a flow channel 22p having a circular cross section within the cylindrical portion 22. The plurality of cylindrical portions 22 are arranged parallel to each other. The outer wall portion 21 has a plurality of communication holes 21o formed in an upper or lower part of the outer wall portion 21. region 21 and are spaced apart from one another in the transverse direction. Each of the cylindrical regions 22 has a plurality of openings 22o which are provided in the cylindrical region 22 and are spaced apart from one another in the transverse direction.

In this configuration, the distributor 20 includes a plurality of cylindrical portions 22 each having a flow channel 22p having a circular cross section within the cylindrical portion 22, and the plurality of cylindrical portions 22 are provided in parallel to each other in the outer wall portion 21 or the hollow portion 21a. This causes refrigerant to flow into a plurality of the flow channels 22p. The refrigerant flowing into each of the flow channels 22p of the plurality of cylindrical portions 22 is distributed to the plurality of heat transfer tubes 1 via the plurality of openings 22o. The present invention therefore makes it possible to make the area of a flow channel 22p per cylindrical portion 22 smaller than in a configuration in which refrigerant is distributed to the plurality of heat transfer tubes 1 via only one inner tube. This makes it possible to reduce a pressure loss of the refrigerant while maintaining the effect of improved refrigerant distribution by including the openings 22o, or to both avoid an increase in the pressure loss and reduce the size of the distributor 20. In addition, the downsizing of the distributor 20 makes it possible to reduce the material cost and reduce the amount of refrigerant of the heat exchanger 100.

Furthermore, the plural cylindrical portions 22 are arranged in the hollow portion 21a of the manifold 20. This makes it unnecessary to change the shape of the header outer wall when assembling the manifold 20 in a header, which facilitates the application.

Furthermore, each of the plurality of cylindrical portions 22 has a circular cylindrical shape. This makes it possible to easily form a flow channel 22p with a circular cross section.

Further, the distributor 20 includes an end divider 23 provided at one end of the outer wall portion 21 in the transverse direction (first direction D1) so that the end divider 23 closes a space located further inside than the outer wall portion 21 and further outside than the plurality of flow channels 22p. This makes it possible to allow the refrigerant to enter only the plurality of flow channels 22p.

Furthermore, a heat exchanger 100 according to Embodiment 1 includes a plurality of heat transfer tubes 1 arranged in a transverse direction (first direction D1) extending in an up-down direction (second direction D2), and two headers (namely, a first header 2a and a second header 2b) provided at the two respective ends of the plurality of heat transfer tubes 1 and which distribute and combine refrigerants, respectively. At least one of the two headers (eg, the first header 2a) includes the distributor 20, and some of the plurality of heat transfer tubes 1 (in the embodiment shown in 1 eighteen heat transfer tubes 1 on the right-hand side in the example shown) are connected to the plurality of connection openings 21o of the manifold 20. This makes it possible to achieve a heat exchanger 100 with high heat exchange performance, since the above-mentioned manifold 20 is included in a header of the heat exchanger 100. In addition, the inclusion of a manifold 20, which makes it possible to both avoid an increase in pressure loss and reduce the size of the manifold 20, allows a reduction in the size of the header and thus a reduction in the size of the heat exchanger 100.

Furthermore, a heat pump device 10 according to Embodiment 1 includes a refrigerant circuit 10a having the heat exchanger 100 and a compressor 11 configured to compress the refrigerant. This makes it possible to improve the energy-saving efficiency of the heat pump device 10 and to reduce the size of the heat pump device 10.

Embodiment 2

5 is a schematic view showing the position of an opening 22o in a cylindrical portion 22 of a distributor 20 according to Embodiment 2. 5 shows a cross section through the cylindrical region 22 perpendicular to the first direction D1. Furthermore, 5 in the cross section of the cylindrical portion 22, the liquid level Ra of the refrigerant R flowing through the flow channel 22p and a liquid level angle θ [degrees]. The term “liquid level angle θ” here means an angle formed in the 5 shown cross section of the cylindrical portion 22 is formed by a reference line L0 drawn vertically downward from the center C1 of the flow channel 22p and a line Lk connecting the center C1 of the flow channel 22p to the position of the liquid level Ra on an inner surface of the cylindrical portion 22.

Embodiment 2 differs from Embodiment 1 in that the position of the opening 22o is restricted, and is identical to Embodiment 1 in the other configurations. Components of Embodiment 2, which are identical to those of Embodiment 1 are denoted by identical reference numerals, and Embodiment 2 will be described with emphasis on the differences from Embodiment 1.

In the 5 In the cross section of the cylindrical portion 22 shown in FIG. 1, each of the plurality of openings 22o is provided at a position at an angle to or immediately sideways from the center C1 of the flow channel 22p, and each of the plurality of openings 22o is provided at a position other than a position immediately below or immediately above the center C1 of the flow channel 22p. That is, no opening 22 is provided immediately below or immediately above the center C1 of the flow channel 22p. By restricting the position of the opening 22o in this way, the liquid refrigerant accumulating in a lower part of the flow channel 22p or the gaseous refrigerant accumulating in an upper part of the flow channel 22p is prevented from flowing out of the opening 22o by gravity alone.

In a case where the opening 22o is provided vertically below, i.e., immediately below, the center C1 of the flow channel 22p in the cylindrical portion 22, when two-phase gas-liquid refrigerant flows into the flow channel 22p, liquid refrigerant preferentially flows out upstream of the distributor 20 in the longitudinal direction (first direction D1). This tends to result in a shortage of refrigerant downstream of the distributor 20 in the longitudinal direction, resulting in uneven distribution.

In the present invention, arranging the opening 22o at a position to the left or right of a vertical line passing through the center C1 of the flow channel 22p in the cylindrical portion 22 causes the opening 22o to be located near the liquid level Ra of the refrigerant R, thereby allowing both the liquid refrigerant and the gaseous refrigerant to easily flow out of the opening 22o, resulting in an improvement in the uniformity of distribution.

6 is a diagram showing an effect of the quality x of the refrigerant on the liquid level angle θ of the 5 The horizontal axis of the refrigerant shown in 6 The graph shown represents the quality x of the refrigerant flowing into the heat exchanger 100, and the vertical axis of the 6 The diagram shown represents the liquid level angle θ of the refrigerant, which is determined by the 5 shown flow channel 22p.

In general, the heat pump device 10 (see 4 ), where the quality of the refrigerant flowing into an evaporator is about 0.2 to 0.8, as in 6 In this case, the liquid level angle θ is an angle of about 50 degrees to 70 degrees, which is smaller than 90 degrees. Therefore, in order to let both the liquid refrigerant and the gaseous refrigerant flow out of the opening 22o, it is only necessary to position the opening 22o at the same position as the liquid level Ra in the cross section of the 5 cylindrical portion 22 shown. In particular, the opening 22o is provided so that the angle formed in 5 formed by the reference line L0 and a line connecting the center C1 of the flow channel 22p to the center of the opening 22o, falls within an angular range of 50 degrees to 70 degrees. Considering that the liquid level Ra in the flow channel 22p is not necessarily constant, the above angular range may be slightly expanded so that the angular position at which the opening 22o is provided falls within a range specified in 6 shown angle range from 40 degrees to 80 degrees.

Although in 5 the angle is formed at the front side in the depth direction (third direction D3) parallel to the depth of the heat exchanger 100, an angle may be formed at the rear side in the depth direction (third direction D3) of the heat exchanger 100. That is, the angular position at which the opening 22o is to be provided is defined here by a positive angle, and the opening 22o may be provided at a front side or at a rear side within the angular range from the reference line L0.

Furthermore, the openings 22o of the cylindrical portions 22 are provided side by side to face each other, as shown in 2 Such a configuration causes refrigerant jets from the openings 22o of the two cylindrical portions 22 to collide with each other, and even if there are imbalances in the distribution of refrigerant to the plurality of flow channels 22p, the effects of the imbalances before distribution to the plurality of heat transfer tubes 1 are reduced.

The statement that the openings 22o of the cylindrical regions 22 face each other can here mean a configuration in which the directions (in 2 indicated by dashed arrows) of blowing out refrigerants from the openings 22o of the cylindrical portions 22, which face each other, are close to each other and are not parallel to each other. In the 2 In the example shown, the two cylindrical portions 22 are provided at a front and a rear in the hollow portion 21a in the outer wall portion 21 of the distributor 20. The front cylindrical ric region 22 has an opening 22o provided below and further back than the center C1 of the flow channel 22p of the cylindrical region 22 (eg, at a 4 o'clock position), and the rear cylindrical region 22 has an opening 22o provided below and further forward than the center C1 of the flow channel 22p of the cylindrical region 22 (eg, at an 8 o'clock position).

Although in the 2 , the positions in the two cylindrical portions 22 where the openings 22o are provided are symmetrical in the direction of arrangement (third direction D3) of the cylindrical portions 22, they do not have to be strictly symmetrical. Even in a case where the front cylindrical portion 22 has an opening 22o at a 4 o'clock position and the rear cylindrical portion 22 has an opening 22o at a 7 o'clock position, it is easier for the refrigerant jets to collide with each other than in a case where the opening 22o is provided at the lowest part of each cylindrical portion 22.

7 is a schematic view showing a first modification of the cylindrical portions 22 of the distributor 20 according to the embodiment 2. As shown in 7 shown, the openings 22o of the cylindrical portions 22 may be arranged next to each other to face away from each other, ie not to face each other. The statement that the openings 22o of the cylindrical portions 22 which are adjacent to each other face away from each other may here mean a configuration in which the directions (in 7 indicated by dashed arrows) of blowing out refrigerant from the openings 22o of the cylindrical portions 22 which are adjacent to each other, away from each other and not parallel to each other.

Although the description has been given so far as an example of a case where there are two cylindrical portions 22, there may be three or more cylindrical portions 22. Even in a case where there are three or more cylindrical portions 22, the positions of the openings 22o may be determined according to the characteristics of the distribution so that there is a region where the openings 22o face each other and a region where the openings 22o do not face each other, or so that all the openings 22o face in a same direction.

In the 7 In the example shown, the cylindrical portion 22 has an opening 22o at the front provided below and further forward than the center C1 of the flow channel 22p of the cylindrical portion 22, and the cylindrical portion 22 has an opening 22o at the rear provided below and further rearward than the center C1 of the flow channel 22p of the cylindrical portion 22. Such an arrangement mitigates the effects of collision between refrigerant jets from the openings 22o of the two cylindrical portions 22 and makes it possible to reduce the pressure loss. Note that the number of flow channels 22p, that is, the number of cylindrical portions 22, is not limited to two.

As mentioned above, the manifold 20 according to Embodiment 2 also includes a plurality of cylindrical portions 22 provided in the hollow portion 21a as in the case of the manifold 20 of Embodiment 1. Embodiment 2 therefore provides similar effects to Embodiment 1.

Further, in the manifold 20 according to Embodiment 2, each of the plurality of openings 22o is provided at a position other than a position immediately below or immediately above a center C1 of the flow channel 22p in a cross section of the corresponding cylindrical portion 22 perpendicular to the transverse direction (first direction D1).

This allows the opening 22o to be located closer to the liquid level Ra of the refrigerant R even in a state where liquid refrigerant tends to accumulate in the lower part of the flow channel 22p by the action of gravity, whereby better distribution of the two-phase gas and liquid refrigerant can be achieved by preventing a mismatch of liquid refrigerant in the longitudinal direction (first direction D1) of the distributor 20.

Further, each of the plurality of openings 22o is provided such that an angle formed in the cross section of the cylindrical portion 22 perpendicular to the transverse direction (first direction D1) by a reference line L0 connecting the center C1 of the flow channel 22p to a point immediately below the center C1 of the flow channel 22p and a line connecting a point where the opening 22o is provided to the center C1 of the flow channel 22p is within an angle range of greater than or equal to 40 degrees and less than or equal to 80 degrees.

Thereby, the opening 22o in a distributor 20 used with an average quality x of refrigerant can be provided at a position closer to the liquid level Ra of the refrigerant R, whereby a more uniform distribution can be achieved by allowing both liquid refrigerant and gaseous refrigerant to easily flow into the opening 22o.

Embodiment 3

8th is a cross-sectional view showing an example of a manifold 20 according to Embodiment 3. Embodiment 3 differs from Embodiment 1 in that a plurality of cylindrical portions 22 are provided in the outer wall portion 21, and is identical to Embodiment 1 in the other configurations. Components of Embodiment 3 that are identical to those of Embodiment 1 are denoted by identical reference numerals, and Embodiment 3 will be described with emphasis on the differences from Embodiment 1.

Each of the plurality of cylindrical portions 22 is provided in the outer wall portion 21 so that in a 8th shown cross-section of the distributor 20 perpendicular to the transverse direction (first direction D1) at least a part of the flow channel 22p is located in the hollow region 21a. In the 8th In the example shown, the two cylindrical portions 22 are coupled together by a portion 21b of the outer wall portion 21 located between the two cylindrical portions 22, and a lower portion of each cylindrical portion 22 projects from the outer wall portion 21 into the hollow portion 21a. The openings 22o are provided in portions of the cylindrical portions 22 that are located in the hollow portion 21a and cause the flow channels 22p inside the cylindrical portions 22 and the hollow portions 21a outside the cylindrical portion 22 to communicate with each other.

As in 8th As shown, a manifold 20 in which flow channels 22p each having a substantially circular cross section are provided in the outer wall portion 21 of the manifold 20 may be integrally formed by extrusion or other methods. Note that the manifold 20 may also be composed of a plurality of components. For example, a cylindrical portion 22 having a flow channel 22p which is substantially circular in cross section may be obtained by combining upper and lower plate-like parts each having a substantially arcuate projection and a recess.

It should be noted that the shapes of the headpieces do not correspond to those in 1 shown forms. Although, for example, in 1 each of the first and second headers 2a and 2b is configured to extend linearly in the first direction D1, it may be formed in the shape of the letter U in plan view having two linear portions extending in the first direction D1 and a bent portion connecting the two linear portions to each other. The distributor 20 of the present invention includes a plurality of flow channels 22p, and the amount of refrigerant flowing through each flow channel 22p is therefore smaller than that of other distributors. Therefore, even in a case where the distributor 20 is provided in a bent portion of a header having the bent portion, the effect of centrifugal force is reduced so that the refrigerant is well distributed.

9 is a schematic view showing a second modification of the manifold 20 according to Embodiment 3. In the second modification, the outer wall portion 21 of the manifold 20 has such a U-shaped bent portion 20b. 9 shows a cross-section of the distributor 20 perpendicular to the third direction D3, which passes through an apex of the curved region 20b.

Each of the many openings 22o is provided in the curved portion 20b further inward than a position immediately below the center C1 of the flow channel 22p in the cylindrical portion 22. In the 9 In the example shown, two cylindrical portions 22 are provided in the upper part of the outer wall portion 21, and each of the inner and outer cylindrical portions 22 has a plurality of openings 22o provided below and further inward than the center C1 of the flow channel 22p. Strictly speaking, of the two line-shaped portions extending transversely in the manifold 20, the rear line-shaped portion has an opening 22o provided below and further forward than the center C1 of the flow channel 22p in each cylindrical portion 22, and the front line-shaped portion has an opening 22o provided below and further rearward than the center C1 of the flow channel 22p in each cylindrical portion 22.

As mentioned above, the distributor 20 according to Embodiment 3 also includes a plurality of cylindrical portions 22 as in the case of the distributor 20 of Embodiment 1. Therefore, Embodiment 3 produces similar effects to Embodiment 1.

Further, in the manifold 20 of Embodiment 3, each of the plurality of cylindrical portions 22 is provided in the outer wall portion 21 so that at least a part of the flow channel 22p is located in the hollow portion 21a in a cross section of the outer wall portion 21 perpendicular to the transverse direction (first direction D1).

This results in a configuration in which the many cylindrical regions 22 are not independent of each other, but are connected via the outer wall portion 21 are coupled to each other. Therefore, for example, even in a case where a process for bending a header including the manifold 20, it is easier to apply force uniformly to each of the cylindrical portions 22 than in a case where the plural cylindrical portions 22 exist independently of each other. In this way, a mutual positional relationship between the constituent parts of the manifold 20 is ensured. As a result, the problem that after machining a header having the manifold 20, an opening 22o provided in each cylindrical portion 22 is crushed or the cylindrical portions 22 interfere with each other can be avoided, which facilitates machining and ensures function.

Further, the outer wall portion 21 has a bent portion 20b, and each of the plurality of openings 22o is provided further inside the bent portion 20b than a position immediately below the center C1 of the flow channel 22p. This causes the opening 22o to be provided at a position in the cylindrical portion 22 opposite to the direction of the centrifugal force (in a 9 shown cross-section of the cylindrical portion 22, the first direction D1) is provided, thereby enabling good distribution even in a case where the liquid level Ra of the refrigerant R is inclined by the centrifugal force.

Embodiment 4

10 is a cross-sectional view showing an example of a distributor 20 according to Embodiment 4. Embodiment 4 differs from Embodiment 1 in that a plurality of cylindrical portions 22 are provided in an intermediate divider 24 disposed in the hollow portion 21a, and is identical to Embodiment 1 in the other configurations. Components of Embodiment 4 that are identical to those of Embodiment 1 are denoted by identical reference numerals, and Embodiment 4 will be described with emphasis on the differences from Embodiment 1.

The distributor 20 of the embodiment 4 is particularly effective in a case where the distributor 20 is in a lower position of the 1 shown first and second head pieces 2a and 2b, i.e. in the second head piece 2b. The following description describes a configuration of the distributor 20 with reference to 10 In a case where the distributor 20 in the 1 shown second head piece 2b.

The outer wall portion 21 of the distributor 20 has, in an upper part of the outer wall portion 21, a plurality of connecting holes 21o into which ends 1e of the plurality of heat transfer tubes 1 are inserted. The distributor 20 includes an intermediate divider 24 extending in the transverse direction (first direction D1). The intermediate divider 24 is arranged in the hollow portion 21a and divides the hollow portion 21a into upper and lower spaces. As shown in 10 As shown, the intermediate divider 24 is connected at its front and rear ends to an inner surface of the outer wall portion 21. In a 10 In the cross-sectional view of the distributor 20 shown, the hollow portion 21a is divided into two spaces, namely a lower space 21a2 and an upper space 21a1, and the cross-sectional area of the upper space 21a1 in which the ends 1e of the plurality of heat transfer tubes 1 are arranged is larger than the cross-sectional area of the lower space 21a2.

The plurality of cylindrical portions 22 are provided in the intermediate divider 24. The embodiment 3 is designed such that the plurality of cylindrical portions 22 are provided in the outer wall portion 21 so that the outer wall portion 21 makes it difficult for the openings 22o or other members to be squeezed. Even in a case like the embodiment 4 in which the plurality of cylindrical portions 22 are provided in the intermediate divider 24 connected to the outer wall portion 21, similar effects to those in the embodiment 3 are obtained.

The intermediate divider 24 has a slit 24a which causes the lower space 21a2 and the upper space 21a1 to communicate with each other. A plurality of the slits 24a are provided in the longitudinal direction (first direction D1) of the distributor 20. Although in the embodiment shown in 10 shown example, only one slot 24a is provided in the depth direction (third direction D3), a plurality of the slots 24a may be provided in the depth direction. The many openings 22o in each of the plurality of cylindrical portions 22 are formed so that one of the lower and upper spaces 21a2 and 21a1, which is further away from the plurality of communication openings 21o, communicates with the flow channels 22p. In a distributor 20 over which heat transfer tubes 1 are arranged, as shown in 10 As shown, the plurality of openings 22o in each of the plurality of cylindrical portions 22 are provided in a lower cylindrical part of the cylindrical portion 22 which projects into the lower space 21a2.

The refrigerant flows into the plurality of flow channels 22p in the distributor 20 are discharged into the lower space 21a2 of the hollow portion 21a through the plurality of openings 22o. The refrigerant discharged from the plurality of flow channels 22p into the lower space 21a2 flows into the upper space 21a2 through the slot 24a of the intermediate divider 24. Space 21a1 in which the ends 1e of the plurality of heat transfer tubes 1 are arranged, and flows into the plurality of heat transfer tubes 1.

As mentioned above, the distributor 20 according to Embodiment 4 also includes a plurality of cylindrical portions 22 as in the case of the distributor 20 of Embodiment 1. Therefore, Embodiment 4 produces similar effects to Embodiment 1.

Further, the distributor 20 of Embodiment 4 includes an intermediate divider 24 which divides the hollow portion 21a into upper and lower spaces and extends in the transverse direction (first direction D1). In addition, a plurality of cylindrical portions 22 are provided in the intermediate divider 24 disposed in the hollow portion 21a. The intermediate divider 24 has a slit 24a which causes the two spaces into which the hollow portion 21a is divided, namely a lower space 21a2 and an upper space 21a1, to communicate with each other. The plurality of openings 22o in each of the plurality of cylindrical portions 22 are formed to cause one of the lower and upper spaces 21a2 and 21a1 which is farther from the plurality of communication openings 21o to communicate with the flow channels 22p.

This causes the many cylindrical portions 22 to be coupled to one another via the intermediate divider 24, so that machining is possible while maintaining the function of the distributor 20 even in a case where the head piece is machined. Furthermore, a space (in which in 10 In the example shown, the lower space 21a2) separated from the plurality of heat transfer tubes 1 by the intermediate divider 24 is provided, and even in a case where the distributor 20 is provided at the lower portion of the heat transfer tubes 1, the direction of the refrigerant is smoothly changed via the separated space. In addition, the refrigerant is discharged upward via the slit 24a of the intermediate divider 24, so that the refrigerant easily flows into the heat transfer tubes 1.

Embodiment 5

11 is a cross-sectional view showing an example of a distributor 20 according to Embodiment 5. 12 is a cross-sectional view showing a cross section along the line BB of the 11 shown distributor 20. In 12 the outline arrows indicate directions in which the refrigerant flows. Furthermore, 12 a distance P1 between heat transfer tubes 1 inserted into the distributor 20. 13 is a cross-sectional view showing a cross section along the line CC- of the 11 shown distributor 20.

Embodiment 5 differs from Embodiment 1 in that a plurality of cylindrical portions 22 are different from each other in the position of an opening 22o in the first direction D1, and is identical to Embodiment 1 in the other embodiments. Components of Embodiment 5 that are identical to those of Embodiment 1 are denoted by identical reference numerals, and Embodiment 5 will be described with emphasis on the differences from Embodiment 1.

In 12 the guide lines of openings 22o provided in the cylindrical portion 22 at the front are shown by solid lines and the guide lines of openings 22o provided in the cylindrical portion 22 at the rear are shown by dashed lines. The openings 22o are all arranged at the same distance P2 from each other in the two cylindrical portions 22. In a case where a distributor 20 includes two cylindrical portions 22, as in 11 As shown, the distance P2 between the openings 22o in a cylindrical region 22, as in 12 shown, be made twice as large as the distance P1 between the heat transfer tubes 1. However, it should be noted that the openings 22o in the cylindrical portion 22 at the front are provided in different positions from the openings 22o at the rear, so that the former positions and the latter positions alternate. As shown in the 12 and 13 As shown, for odd numbers of the plurality of heat transfer tubes 1 connected to the manifold 20, counted from the left, refrigerant is discharged from the openings 22o provided in the front cylindrical portion 22. Further, for even numbers of the plurality of heat transfer tubes 1, counted from the left, refrigerant is discharged from the openings 22o provided in the rear cylindrical portion 22.

For example, if the distance P1 between the heat transfer tubes 1 is so small as to be less than 10 [mm], attempting to provide a larger number of openings 22o than the number of heat transfer tubes 1 in each cylindrical portion 22 results in the distance between the openings 22o being reduced. This makes it difficult to form the openings 22o in the cylindrical portion 22 during manufacture and makes the cylindrical portion 22 weak against pressure.

To solve this problem, the distributor 20 according to the embodiment 5, as mentioned above, is designed such that the openings 22o of the cylindrical portions 22 are arranged side by side in various different positions which alternate in the transverse direction (first direction D1).

This increases the distance P2 between the openings 22o provided in each cylindrical portion 22, makes it easy to provide one opening 22o per heat transfer tube 1, and makes it possible to ensure good distribution. In addition, increasing the distance P2 between the openings 22o makes it possible to avoid difficulties in manufacturing and improves pressure resistance.

Embodiment 6

14 is a cross-sectional view showing an example of a manifold 20 according to Embodiment 6. Embodiment 6 differs from Embodiment 1 in the number of openings 22o provided in each cylindrical portion 22 in a cross section of the manifold 20 perpendicular to the transverse direction (first direction D1), and is identical to Embodiment 1 in the other configurations. Components of Embodiment 6 that are identical to those of Embodiment 1 are denoted by identical reference numerals, and Embodiment 6 will be described with emphasis on the differences from Embodiment 1.

As in 14 shown, a plurality of the openings 22o are in the same plane (ie a plane in 14 shown cross-section). In the 14 In the example shown, two cylindrical portions 22 are provided at a front side and at a rear side in the hollow portion 21a in the outer wall portion 21 of the distributor 20. The front cylindrical portion 22 has an opening 22o provided below and further forward than the center C1 of its flow channel 22p and an opening 22o provided below and further rearward than the center C1 of the flow channel 22p, and the rear cylindrical portion 22 also has an opening 22o provided below and further forward than the center C1 of its flow channel 22p and an opening 22o provided below and further rearward than the center C1 of the flow channel 22p.

The provision of a plurality of openings 22o in a cross-section of a cylindrical region 22 enables better distribution even in the case where there are imbalances in the distribution of liquid refrigerant in the cylindrical region 22, since the presence of the plurality of openings 22o causes a uniform distribution of the refrigerant flowing into the heat transfer tubes 1. The presence of a plurality of openings 22o in a cross-section of a cylindrical region 22 not only ensures uniformity, but also results in a configuration in which an unequal proportion of liquid or gas is intentionally distributed. The plurality of openings 22o need not be provided in the same plane over the entire distributor 20. In a configuration in which a plurality of openings 22o in the same plane are provided only in a part of the manifold 20, heat exchange in the entire heat exchanger including the manifold 20 is efficiently performed by, for example, intentionally distributing less refrigerant in a region where there is a reduction in heat exchange amount due to pipes or other components provided around it when the manifold 20 is mounted in a product or other articles.

Further, the shapes of the openings 22o in the embodiment 6 may be slit-like shapes, and the number of the openings 22o may be less than or equal to the number of the heat transfer tubes 1, that is, the number of the communication openings 21o provided in the outer wall portion 21. In addition, the openings 22o do not have to be identical in shape or size throughout the entire cylindrical portion 22, and the area of each of the openings 22o only in a part of the cylindrical portion 22 may be large. In other words, the size of each of the openings 22o provided in one part of the cylindrical portion 22 may be different from the size of each of the openings 22o provided in another part of the cylindrical portion 22. For example, by varying the shape and size of the openings 22o in the cylindrical region 22 or by providing as many or fewer openings 22o as or as heat transfer tubes 1, the refrigerant is distributed with an intentionally disproportionately higher proportion of liquid or gas in a certain region.

As mentioned above, in the distributor 20 according to the embodiment 6, a plurality of the openings 22o are provided in one of the cylindrical portions 22 in an identical plane perpendicular to the flow channel 22p. This enables better distribution even in a case where there are imbalances in the distribution of the liquid refrigerant in the cylindrical portion 22, since the presence of the many openings 22o changes the distribution of the refrigerant flowing into the heat transfer tubes 1. Furthermore, by appropriately adjusting the number of openings 22o provided in the same cross section of the cylindrical portion 22, not only uniformity can be ensured, but also a deliberately uneven proportion of liquid or gas can be distributed, which has the effect of increasing the degree of freedom of distribution.

It should be noted that it is possible to combine one of the embodiments with another or to modify or omit one of the embodiments accordingly. For example, in each of the embodiments, the openings 22o may also be slit-shaped, and the number of openings 22o may be less than or equal to the number of heat transfer tubes 1, that is, the number of connection openings 21o provided in the outer wall portion 21. In addition, the openings 22o do not have to be identical in shape or size in the entire cylindrical portion 22, and the area of each of the openings 22o in only a part of the cylindrical portion 22 may be large.

List of reference symbols

1

Heat transfer tube

1e

End

2a

first distributor

2 B

second distributor

3a

Pipe

3b

Pipe

4

Divider

10

Heat pump device

10a

Refrigerant circulation

11

compressor

12

Flow switch device

13

Heat exchanger

14

Pressure reducer

20

Distributor

20b

curved area

21

Exterior wall area

21a

hollow area

21a1

upper room

21a2

lower room

21b

Area

21o

Connection opening

22

cylindrical area

22o

opening

22p

Flow channel

23

End divider

23a

opening

24

Intermediate divider

24a

slot

100

Heat exchanger

C1

center

D1

first direction

D2

second direction

D3

third direction

L0

Reference line

L1

line

P1

Distance

P2

Distance

R

Refrigerant

Ra

Fluid level

x

Degree

θ

Liquid level angle

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• JP 6523858 A [0003]

Claims (16)

A distributor comprising: an outer wall portion having a cylindrical shape and extending in a transverse direction; and a plurality of cylindrical portions extending in the transverse direction, the plurality of cylindrical portions being provided in the outer wall portion or in a hollow portion within the outer wall portion and each having a flow channel having a circular cross section within the cylindrical portion, the plurality of cylindrical portions being provided parallel to each other, the outer wall portion having a plurality of communication openings formed in an upper or lower part of the outer wall portion and spaced apart from each other in the transverse direction, each of the plurality of cylindrical portions having a plurality of openings provided in the cylindrical portion and spaced apart from each other in the transverse direction. Distributor to Claim 1 wherein each of the plurality of cylindrical portions in the outer wall portion is provided such that at least a portion of the flow channel is located in the hollow portion in a cross section of the outer wall portion perpendicular to the transverse direction. Distributor to Claim 1 or 2 wherein each of the plurality of openings is provided at a position other than a position immediately below or immediately above the center of the flow channel in a cross section of a corresponding one of the plurality of cylindrical regions perpendicular to the transverse direction. Distributor to Claim 3 wherein each of the plurality of openings is provided such that an angle formed in the cross section of a corresponding one of the plurality of cylindrical portions perpendicular to the transverse direction by a reference line connecting the center of the flow channel to a point immediately below the center of the flow channel and a line connecting a point at which the opening is provided to the center of the flow channel is within an angular range of greater than or equal to 40 degrees and less than or equal to 80 degrees. Distributor to Claim 3 or 4 , wherein the plurality of openings of the plurality of adjacent cylindrical regions are provided facing each other. Distributor to Claim 3 or 4 , wherein the plurality of openings of the plurality of adjacent cylindrical portions are provided so as to face away from each other. Distributor to Claim 3 or 4 wherein the outer wall portion has a curved portion, and each of the plurality of openings in the curved portion is provided further inward than a position immediately below the center of the flow channel in a corresponding one of the plurality of cylindrical portions. Distributor according to one of the Claims 1 until 7 , wherein the many openings of the plurality of cylindrical regions are provided side by side in different positions alternating in the transverse direction. Distributor according to one of the Claims 1 until 8th , wherein one of the plurality of cylindrical regions has the many openings in an identical plane perpendicular to the flow channel. Distributor according to one of the Claims 1 until 9 , each of the many openings having a slot shape. Distributor according to one of the Claims 1 until 10 , wherein the number of the plurality of openings provided in one of the plurality of cylindrical portions is less than or equal to the number of the plurality of communication openings provided in the outer wall portion. Distributor according to one of the Claims 1 until 11 wherein the size of each of the plurality of openings provided in one region of one of the plurality of cylindrical regions is different from the size of each of the plurality of openings provided in another region of the one of the plurality of cylindrical regions. Distributor according to one of the Claims 1 until 12 , wherein each of the plurality of cylindrical regions has a circular cylindrical shape. Distributor according to one of the Claims 1 until 13 further comprising: an end divider provided at one end of the outer wall portion in the transverse direction such that the end divider closes a space located further inside than the outer wall portion and further outside than a plurality of the flow channels. A heat exchanger comprising: a plurality of heat transfer tubes arranged in the transverse direction and extending in an up-down direction; and two headers provided at both respective ends of the plurality of heat transfer tubes. which distribute and combine refrigerant, with at least one of the two head pieces directing the distributor to one of the Claims 1 until 14 wherein a portion of the plurality of heat transfer tubes is connected to the plurality of connecting openings of the distributor. Heat pump device that has a refrigerant circuit with the heat exchanger Claim 15 and a compressor designed to compress the refrigerant.

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