Fan member, fan, fan unit, air conditioner, heat pump device, and method for manufacturing fan member

By controlling the melt flow rate of the resin and the flow resistance and porosity of the porous components, the resin filling problem of the porous components during insert molding was solved, achieving a tight bond between the porous components and the resin components and maintaining the noise reduction effect, thus improving the performance of the fan unit.

CN120981663BActive Publication Date: 2026-06-19DAIKIN INDUSTRIES LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
DAIKIN INDUSTRIES LTD
Filing Date
2024-03-28
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In the prior art, when porous components are molded as inserts, the resin tends to fill the pores, resulting in poor noise reduction and difficulty in integral molding with the resin component.

Method used

By controlling the melt flow rate (MFR) of the resin to be above 2 g/10 min and below 45 g/10 min, and combining this with the design of the porous component having a flow resistance of above 0.5 kPa and below 1.1 kPa, a porosity of above 20% and below 90%, and a pore size of above 50 μm and below 500 μm, the porous component and the resin component can be properly integrally molded.

Benefits of technology

While maintaining the noise reduction effect of porous components, a tight bond and integral molding of porous components and resin components are achieved, which improves the noise reduction effect and fan performance of the fan unit.

✦ Generated by Eureka AI based on patent content.

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Abstract

The fan component (40) comprises: a porous component (41) having multiple pores; and a resin component (42) integrally formed with the porous component (41). The melt flow rate (MFR) of the resin constituting the resin component (42) is 2 g / 10 min or more and 45 g / 10 min or less. A portion of the multiple pores is filled with resin.
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Description

Technical Field

[0001] This disclosure relates to fan components, fans, fan units, air conditioners, heat pump devices, and methods for manufacturing fan components. Background Technology

[0002] A known technique involves using porous components in fan parts to reduce noise from a rotating fan unit. Patent Document 1 discloses a fan with a porous component. When the fan rotates, the pores in the porous component allow airflow to pass from the upper surface of the fan towards the lower surface. Therefore, by using a fan with a porous component, the noise of the rotating fan unit can be reduced.

[0003] Furthermore, as a method for manufacturing fan components with porous parts, there is a known method of integrally molding the porous part and the resin part. Patent Documents 2 and 3, as examples, disclose an insert-based molding method in which the porous part is fixed inside a mold and resin is injected into the mold.

[0004] Existing technical documents

[0005] Patent documents

[0006] Patent Document 1: Japanese Patent Application Publication No. 2021-134751

[0007] Patent Document 2: Japanese Patent Application Publication No. 4-012199

[0008] Patent Document 3: Japanese Utility Model Application Publication No. 6-025597 Summary of the Invention

[0009] The problem that the invention aims to solve

[0010] When insert molding is used for porous components as in Patent Documents 2 and 3, there is a problem that resin may flow into the pores of the porous component, causing the resin to fill the pores. If the pores of the porous component disappear, it may be impossible to obtain a sufficient noise reduction effect through the porous component.

[0011] The purpose of this disclosure is to provide a fan component, fan, fan unit, air conditioner, heat pump device, and a method for manufacturing a fan component that can maintain the noise reduction effect provided by the porous component while properly integrally molding the porous component and the resin component.

[0012] Methods for solving problems

[0013] The first viewpoint for solving this problem includes a fan component comprising: a porous component having a plurality of pores; and a resin component integrally formed with the porous component, wherein the melt flow rate (MFR) of the resin constituting the resin component is 2 g / 10 min or more and 45 g / 10 min or less, and the resin is filled in a portion of the plurality of pores.

[0014] According to this structure, since the melt flow rate (MFR) of the resin is less than 45 g / 10 min, the resin-filled pores in the porous component can be reduced. Therefore, the porous component and the resin component can be properly integrally molded while maintaining the noise reduction effect of the porous component.

[0015] Regarding the fan component of the second perspective, in the fan component of the first perspective, the melt flow rate (MFR) of the resin is 5 g / 10 min or more and 40 g / 10 min or less. According to this structure, since the melt flow rate (MFR) of the resin is 40 g / 10 min or less, it is possible to further reduce the resin-filled pores in the porous component.

[0016] Regarding the fan component of the third viewpoint, in the fan component of the second viewpoint, the resin is formed from a resin with a melt flow rate (MFR) of 5 g / 10 min or more and 35 g / 10 min or less. According to this structure, since the melt flow rate (MFR) of the resin is 35 g / 10 min or less, it is possible to further reduce the resin-filled pores in the porous component.

[0017] Regarding the fan component of the fourth viewpoint, in the fan component of any of the first to third viewpoints, the flow resistance of the porous component is 0.5 kPa or more and 1.1 kPa or less. According to this structure, since the flow resistance of the porous component is 0.5 kPa or more and 1.1 kPa or less, it is possible to integrally mold the porous component with the resin component while maintaining the noise reduction effect brought about by the porous structure.

[0018] Regarding the fan component of the fifth viewpoint, in the fan component of any of the first to fourth viewpoints, the porosity of the porous component is 20% or more and 90% or less, and the pore size of the porous component is 50 μm or more and 500 μm or less. According to this structure, since the porosity of the porous component is 20% or more and 90% or less, and the pore size of the porous component is 50 μm or more and 500 μm or less, it is possible to further reduce the number of resin-filled pores in the porous component.

[0019] Regarding the fan component of the sixth viewpoint, in the fan component of the fifth viewpoint, the porosity of the porous component is 30% or more and 90% or less, and the pore size of the porous component is 90 μm or more and 300 μm or less. According to this structure, since the porosity of the porous component is 30% or more and 90% or less, and the pore size of the porous component is 90 μm or more and 300 μm or less, it is possible to further reduce the number of resin-filled pores in the porous component.

[0020] Regarding the fan component of the seventh viewpoint, in the fan component of any of the first to sixth viewpoints, the porous component has a pore-filled portion where the plurality of pores of the porous component are filled with resin. According to this structure, since the pores of the porous component are filled with resin at the filling portion, the porous component can be properly bonded to the resin component.

[0021] Regarding the fan component of the eighth viewpoint, in the fan component of any of the first to seventh viewpoints, the porous component has a central portion and a peripheral portion surrounding the central portion, the flow resistance of the peripheral portion being different from the flow resistance of the central portion. According to this structure, by making the flow resistance of the central portion different from the flow resistance of the peripheral portion in the porous component, the bonding between the porous component and the resin component can be properly operated.

[0022] The ninth viewpoint discloses a fan component comprising a porous component and a resin component integrally molded with the porous component. The porous component has a porosity of 20% or more and 90% or less, and a pore size of 50 μm or more and 500 μm or less. According to this structure, since the porous component has a porosity of 20% or more and 90% or less, and a pore size of 50 μm or more and 500 μm or less, the number of resin-filled pores in the porous component can be reduced. Therefore, the porous component and the resin component can be appropriately integrally molded while maintaining the noise reduction effect of the porous component.

[0023] The fan of the tenth viewpoint is composed of the fan components described in any of the first to ninth viewpoints. Based on this structure, a fan composed of fan components can be provided.

[0024] The fan unit of the eleventh viewpoint includes the fan and flare described in the tenth viewpoint. Based on this structure, a fan unit with a fan and flare can be provided.

[0025] The air conditioner of the twelfth viewpoint includes the fan unit described in the eleventh viewpoint. Based on this structure, an air conditioner with a fan unit can be provided.

[0026] The heat pump device of the thirteenth viewpoint includes the fan unit described in the eleventh viewpoint. Based on this structure, a heat pump device with a fan unit can be provided.

[0027] The fourteenth viewpoint describes a method for manufacturing a fan component, comprising: a porous component having multiple pores; and a resin component integrally formed with the porous component. The method includes the step of insert molding the porous component with a resin having a melt flow rate (MFR) of 2 g / 10 min or more and 45 g / 10 min or less. According to this structure, since the resin's melt flow rate (MFR) is 2 g / 10 min or more and 45 g / 10 min or less, it is difficult for the resin to flow into the pores of the porous component during insert molding. Because the resin is difficult to flow into the pores of the porous component, the pores of the porous component are easily maintained. By using a resin with such a melt flow rate (MFR), it is possible to properly insert the porous component while maintaining its noise reduction effect. Attached Figure Description

[0028] Figure 1 This is a schematic diagram of the outdoor unit.

[0029] Figure 2 This is the front view of the fan.

[0030] Figure 3 This is a magnified view of the fan blades.

[0031] Figure 4 This is a schematic diagram showing a device for measuring flow resistance.

[0032] Figure 5 This is a schematic diagram illustrating the manufacturing process of a fan component.

[0033] Figure 6 This is a schematic diagram illustrating the manufacturing process of a fan component.

[0034] Figure 7 It is a graph showing the relationship between porosity, pore size and flow resistance of porous components.

[0035] Figure 8 This is a graph showing the relationship between porosity, pore size, and noise reduction effect of porous components.

[0036] Figure 9 This is a graph showing the noise reduction effect of a fan component relative to the MFR of the resin constituting the resin component, based on the flow resistance of the porous component. Detailed Implementation

[0037] <Implementation Method>

[0038] Reference Figures 1 to 9 The air conditioner 10A, fan unit 20, fan 30, fan component 40, and the manufacturing method of fan component 40 according to the embodiments will be described.

[0039] Air conditioner

[0040] like Figure 1 As shown, the air conditioner 10A of this embodiment is a device that uses a vapor compression refrigeration cycle to adjust the indoor air temperature. The air conditioner 10A of this embodiment includes an outdoor unit 10 and an indoor unit (not shown). In addition, the air conditioner is not limited to a device that uses a vapor compression refrigeration cycle to adjust the indoor air temperature; for example, it may include concepts such as an air purifier or a ventilation device.

[0041] <Outdoor unit>

[0042] Outdoor unit 10 is the outdoor unit 10 of air conditioner 10A. Air conditioner 10A is used for cooling or heating indoor spaces such as residences and offices. Air conditioner 10A can also be used for cooling or heating indoor spaces such as warehouses for storing goods or work spaces for processing goods.

[0043] Figure 1 This is a schematic diagram showing the outdoor unit 10 viewed from the front. Figure 1 The example shown is a vertically mounted outdoor unit 10, but the outdoor unit 10 can also be horizontally mounted. The outdoor unit 10 is connected to the indoor unit of the air conditioner 10A, for example, via connecting pipes. The indoor unit contains equipment such as an indoor expansion valve and an indoor heat exchanger.

[0044] The outdoor unit 10, for example, includes a lower unit 11. The lower unit 11 has a lower housing 12. The lower housing 12 houses components constituting the refrigerant circuit, such as a compressor, an outdoor heat exchanger, an outdoor expansion valve, a liquid receiver, and an oil separator; as well as control equipment with electronic components for controlling the refrigerant circuit. The air conditioner 10A includes a fan unit 20. The outdoor unit 10 includes a fan unit 20. The fan unit 20 is connected to the lower unit 11, for example. The indoor unit of the air conditioner 10A may also include a fan unit 20.

[0045] <Fan Unit>

[0046] The fan unit 20 includes a fan 30 and a flare 21. In this embodiment, the fan 30 is arranged to extend vertically around a central axis of rotation. The fan unit 20 is configured, for example, to blow air drawn into the lower unit 11 upwards via the flare 21 using the fan 30. In this embodiment, the flare 21 is arranged to allow airflow KR to pass through from bottom to top. The flare 21 has a cylindrical portion 21A disposed around the fan 30. The cylindrical portion 21A is made of resin, for example.

[0047] The fan unit 20 includes, for example, a motor 22 and a fan housing 23. The rotating shaft of the motor 22 is connected to the fan 30 to cause the fan 30 to rotate. The motor 22 is housed, for example, in a motor housing.

[0048] The fan housing 23 is disposed, for example, on the upper part of the lower housing 12. The fan housing 23, for example, houses the fan 30, the horn 21, and the motor 22. The fan housing 23, for example, has an outlet 23A through which air blown from the horn 21 passes, and a support portion 23B supporting the outlet 23A. The fan housing 23 is made of resin, for example.

[0049] <Fan>

[0050] like Figure 2 As shown, the fan 30 in this embodiment is an axial fan. The fan 30 can also be a centrifugal fan. The fan 30 includes a hub 31 and blades 32 disposed around the hub 31. The hub 31 is cylindrical. The hub 31 and the blades 32 are integrally formed. A shaft hole 31A for mounting the rotating shaft of the motor 22 is formed in the hub 31.

[0051] A plurality of blades 32 are arranged on the hub 31 at angular intervals in the circumferential direction. In this embodiment, the number of blades 32 is three, but the number of blades 32 may be less than three or more. The plurality of blades 32 are arranged radially outward from the hub 31 toward the rotational radius direction of the fan 30. When the fan 30 is viewed from the front or the back, adjacent blades 32 do not overlap. The blades 32 are formed as plates that are smoothly curved along the rotational radius direction and the rotational direction. The plurality of blades 32 have the same shape.

[0052] <Fan components>

[0053] like Figure 1 and Figure 2 As shown, the fan unit 20 includes a fan component 40. The fan component 40 is disposed in the fan unit 20 in such a way that it reduces the noise generated in the fan unit 20 by contacting the airflow KR. The component in the fan unit 20 that contacts the airflow KR is, for example, composed of the fan component 40. In this embodiment, the fan 30 is composed of the fan component 40.

[0054] The fan component 40 includes a porous component 41 and a resin component 42 integrally formed with the porous component 41. The fan component 40 is formed from the resin component 42. In this embodiment, the blade 32 is composed of the porous component 41 and the resin component 42. The porous component 41 is disposed, for example, on the blade surface 32A of each blade 32. The blade surface 32A is, for example, a surface disposed facing the airflow KR. The thickness of the porous component 41 is approximately the same as the thickness of the resin component 42. The location where the porous component 41 is disposed is not limited to the blade 32. The hub 31 may also be configured to include the porous component 41.

[0055] Fan component 40 is formed by inserting porous component 41 into resin 42A (see reference) that forms resin component 42. Figure 6 The porous component 41 is formed, for example, from a porous body. Examples of materials forming the porous component 41 include resin, ceramic, and metal. Examples of resins include foaming resins. Specific examples of resin-based porous components 41 include foams made of polystyrene resin (PS), foams made of ABS resin, foams made of styrene acrylic acid (AS), or foams made of polypropylene (PP). The porous component 41 may also be composed of a glass fiber reinforced styrene-acrylonitrile resin (ASG) foam. The porous component 41 may also be a porous sintered body made of ceramic or metal. The porous component 41 may also be a metal mesh.

[0056] The porous component 41 has multiple pores. A portion of these pores is filled with resin 42A. The porous component 41 has a porous structure. The porous structure has through-holes that penetrate the blade 32 in the thickness direction. The multiple pores included in the porous component 41 are interconnected, thereby the through-holes of the porous structure penetrate the blade 32 in the thickness direction. Airflow KR can pass through the pores. Airflow KR passing through the pores of the porous component 41 reduces noise caused by the fan unit 20.

[0057] The resin component 42 is configured, for example, to prevent the flow of airflow KR. The resin component 42 is, for example, made of resin 42A. The resin component 42 is, for example, made of thermoplastic resin. The resin component 42 is, for example, made of polystyrene resin, ABS resin, glass fiber reinforced styrene-acrylonitrile resin (ASG), or glass fiber reinforced polypropylene resin (PPGF).

[0058] The porous component 41 is formed, for example, of the same type of resin as the resin component 42. If the porous component 41 is a foam made of polystyrene resin, then the resin component 42 is made of polystyrene resin. If the porous component 41 is a foam made of ABS resin, then the resin component 42 is made of ABS resin. If the porous component 41 is a foam made of styrene-acrylic acid, then the resin component 42 is made of glass fiber reinforced styrene-acrylonitrile resin. If the porous component 41 is a foam made of polypropylene, then the resin component 42 is made of glass fiber reinforced polypropylene resin. The porous component 41 may be formed of a different type of resin than the resin component 42, or it may be formed of a different material than the resin.

[0059] When the porous component 41 is made of the same material as the resin component 42, during the insert molding of the fan component 40, the porous component 41 and the resin component 42 easily adhere tightly together when the resin component 42 flows into the pores of the porous component 41. By making the porous component 41 and the resin component 42 adhere tightly to each other, the bonding strength between the porous component 41 and the resin component 42 during insert molding can be improved.

[0060] like Figure 3 and Figure 6 As shown, parameters representing the flowability of resin 42A relative to porous component 41 include, for example, the melt flow rate (MFR) of resin 42A under specified conditions. For example, the higher the MFR, the easier it is for resin 42A to flow to porous component 41 during insert molding. MFR is, for example, melt mass flow rate. Specified conditions are, for example, test conditions according to ISO 1133. As an example, when resin component 42 is polystyrene resin, the specified conditions for measuring the MFR of resin 42A are according to ISO 1133, with a temperature of 200°C and a load of 5 kg.

[0061] Under specified conditions, the MFR of resin 42A constituting resin component 42 is 2 g / 10 min or more and 45 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 2 g / 10 min or more and 40 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 2 g / 10 min or more and 35 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 2 g / 10 min or more and 30 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 5 g / 10 min or more and 45 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 5 g / 10 min or more and 40 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 5 g / 10 min or more and 35 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 5 g / 10 min or more and 25 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 7 g / 10 min or more and 16.5 g / 10 min or less. Under specified conditions, the MFR of resin 42A can be 7 g / 10 min, and under specified conditions, the MFR of resin 42A can be 16.5 g / 10 min. As an example, when resin 42A is polystyrene resin, the specified conditions for measuring the MFR of resin 42A are based on ISO 1133, with a temperature of 200°C and a load of 5 kg. When the MFR of resin 42A is 2 g / 10 min or more and 45 g / 10 min or less, resin 42A is difficult to flow in the porous component 41.

[0062] Parameters indicating the ease of flow of resin 42A relative to porous component 41 include, for example, the flow resistance of porous component 41. For instance, the greater the flow resistance of porous component 41, the more difficult it is for resin 42A to flow to porous component 41 during insert molding. The flow resistance of porous component 41 is adjusted, for example, during the formation stage of porous component 41. The flow resistance of porous component 41 is adjusted, for example, by the particle size of the raw materials constituting porous component 41.

[0063] In this embodiment, the flow resistance of the porous component 41 represents the difficulty of air flow within the porous structure of the porous component 41. For example, the greater the flow resistance of the porous component 41, the more difficult it is for the airflow KR to pass through the porous component 41. If the flow resistance of the porous component 41 is large, there is a tendency for the pore size of the porous component 41 to be small or the porosity of the porous component 41 to be low, thus making it difficult for the resin 42A to flow relative to the porous component 41.

[0064] Figure 4An example of a measuring device 60 for measuring the flow resistance of a porous component 41 is shown. The measuring device 60 is a tool for measuring the flow resistance of a test piece 61. The measuring device 60 has a first housing 62 and a second housing 63. The first housing 62 forms a first chamber 64. The second housing 63 forms a second chamber 65. The first chamber 64 and the second chamber 65 are connected by a connecting hole 66. The connecting hole 66 is provided to pass through the first housing 62 and the second housing 63. The test piece 61 is disposed in the connecting hole 66. The test piece 61 has a porous structure with a through hole extending from the first chamber 64 to the second chamber 65. Air passes through the porous structure of the test piece 61, thereby enabling movement between the first chamber 64 and the second chamber 65.

[0065] The measuring device 60 includes a first flow path 67, a second flow path 68, and a blower 69. The first flow path 67 is connected to the first chamber 64 in a manner that communicates with the outside of the first housing 62. The second flow path 68 is connected to the second chamber 65 in a manner that communicates with the outside of the second housing 63. The first flow path 67, the first chamber 64, the second chamber 65, and the second flow path 68 together form an air flow path 70 within the measuring device 60. The blower 69 supplies air into the measuring device 60 from the first flow path 67. The air supplied by the blower 69 flows through the air flow path 70. The air flowing through the air flow path 70 exits through the second flow path 68 to the outside of the measuring device 60.

[0066] The measuring device 60 has a first flow meter 71 and a second flow meter 72. The first flow meter 71 and the second flow meter 72 are, for example, air volume meters. The first flow meter 71 is configured to measure the air volume passing through the first flow path 67. The second flow meter 72 is configured to measure the air volume passing through the second flow path 68.

[0067] The measuring device 60 includes a first differential pressure gauge 73 and a second differential pressure gauge 74. The first differential pressure gauge 73 and the second differential pressure gauge 74 are, for example, pressure gauges. The first differential pressure gauge 73 is configured to measure the pressure within the first chamber 64. The second differential pressure gauge 74 is configured to measure the pressure within the second chamber 65. With air supplied to the measuring device 60 via the blower 69, the pressure difference between the first chamber 64 and the second chamber 65 represents the flow resistance of the test piece 61.

[0068] The measuring device 60 is configured such that, when the airflow through the first flow path 67 is 100 L / min, the difference between the airflow through the first flow path 67 and the airflow through the second flow path 68 is less than 1% of the airflow through the first flow path 67. The first housing 62 and the second housing 63 are configured such that air cannot move between the first chamber 64 and the second chamber 65 from any part other than the connecting hole 66. The test piece 61 is disposed such that it is sandwiched between the first housing 62 and the second housing 63. At this time, the portions of the first housing 62 that contact the test piece 61, and the portions of the second housing 63 that contact the test piece 61, are sealed to prevent air leakage. The air passage area on the surface of the test piece 61 is set to be the same regardless of the type of test piece 61. The area of ​​the test piece 61 exposed to the first chamber 64 is set to be the same regardless of the type of test piece 61. The area of ​​the test piece 61 exposed to the second chamber 65 is set to be the same regardless of the type of test piece 61. The blower 69 is configured to ensure 100 L / min regardless of the pressure loss caused by the measuring device 60 and the test piece 61, so as to keep the through air volume measured by the first flow meter 71 and the second flow meter 72 stable.

[0069] The flow resistance of the porous component 41 is, for example, 0.2 kPa or more and 1.2 kPa or less. The flow resistance of the porous component 41 can be, for example, 0.3 kPa or more and 1.1 kPa or less. The flow resistance of the porous component 41 can be, for example, 0.35 kPa or more and 1.0 kPa or less. By setting the flow resistance of the porous component 41 to 0.2 kPa or more, the resin 42A is difficult to flow in the porous component 41. On the other hand, by setting the flow resistance of the porous component 41 to 1.2 kPa or less, the resin 42A is adequately filled into the pores of the porous component 41, thus allowing the resin component 42 to bond with the porous component 41.

[0070] The flow resistance of the porous component 41 can be, for example, 0.4 kPa or more and 1.1 kPa or less. The flow resistance of the porous component 41 can be, for example, 0.5 kPa or more and 1.1 kPa or less. By setting the flow resistance of the porous component 41 to 0.4 kPa or more, the porous structure of the porous component 41 is properly maintained in the fan component 40. By setting the flow resistance of the porous component 41 to 1.1 kPa or less, the porous structure of the porous component 41 is maintained, and the resin component 42 can be properly bonded to the porous component 41.

[0071] The flow resistance of the porous component 41 is, for example, greater than the following value: this value is obtained by multiplying the MFR of resin 42A by the gravitational acceleration and then dividing the product by the cross-sectional area of ​​the porous component 41. The cross-sectional area of ​​the porous component 41 is the cross-sectional area of ​​the porous component 41 when the blade 32 is viewed from the thickness direction.

[0072] The flow resistance of the porous component 41 is set based on its pore size and porosity. A smaller pore size results in greater flow resistance, while a larger pore size results in lower flow resistance. Conversely, a lower porosity results in greater flow resistance, while a higher porosity results in lower flow resistance.

[0073] The pore size of the porous component 41 is, for example, the average pore size of the pores present in the porous component 41. There are no particular limitations on the method for measuring the average pore size; for example, it can be measured by gas adsorption, also known as the BET method. The conditions for gas adsorption are, for example, test conditions according to JIS Z8831-2 2010 or ISO 15901-2 2006. The conditions for gas adsorption can also be test conditions according to JIS Z8830 2013 or ISO 9277 2010. The porosity of the porous component 41 is, for example, the ratio of the total volume of the pores present in the porous component 41 to the total volume of the porous component 41.

[0074] The porous component 41 has a porosity of 20% or more and 90% or less, and a pore size of 50 μm or more and 500 μm or less. Alternatively, the porous component 41 may have a porosity of 30% or more and 90% or less, and a pore size of 90 μm or more and 300 μm or less. Or, the porous component 41 may have a porosity of 30% or more and 80% or less, and a pore size of 100 μm or more and 200 μm or less.

[0075] like Figure 3 As shown, the porous component 41 has a central portion 43 and a peripheral portion 44. Figure 3 In the diagram, the boundary between the central portion 43 and the peripheral portion 44 is indicated by a dashed line. The central portion 43 is the part of the porous component 41 where the resin 42A does not flow and the porous structure is exposed. In the central portion 43, the pores of the porous component 41 are maintained in such a way that through holes of the porous component 41 are formed by utilizing the pores of the porous component 41 after the insert of the fan component 40 is molded.

[0076] The area of ​​the central part 43 is, for example, 2400 mm². 2 Above and 6200mm 2The area of ​​the central section 43 can be, for example, 2800 mm². 2 Above and 5800mm 2 The area of ​​the central part 43 can be, for example, 3200 mm². 2 Above and 5400mm 2 The area of ​​the central portion 43 is, for example, the area of ​​the central portion 43 disposed in the porous component 41 of a blade 32.

[0077] The peripheral portion 44 is located, for example, around the central portion 43. The peripheral portion 44 is the portion of the porous component 41 from which the resin 42A flows. After the insert of the fan component 40 is molded, the peripheral portion 44 may or may not maintain the pores of the porous component 41. The width D1 of the peripheral portion 44 is, for example, 2 mm or more and 6 mm or less. The width D1 of the peripheral portion 44 is, for example, 2.5 mm or more and 5.5 mm or less. The width D1 of the peripheral portion 44 is, for example, 3 mm or more and 5 mm or less. The width D1 of the peripheral portion 44 is, for example, the length from the end of the central portion 43 to the end of the porous component 41. The width D1 of the peripheral portion 44 is, for example, the shortest of the lengths from the end of the central portion 43 to the end of the porous component 41.

[0078] The pore diameter of the peripheral portion 44 can be the same as or smaller than that of the central portion 43. The porosity of the peripheral portion 44 can be the same as or smaller than that of the central portion 43. In this embodiment, when the pore diameter of the peripheral portion 44 is the same as that of the central portion 43, the porosity of the peripheral portion 44 is smaller than that of the central portion 43. In this embodiment, when the porosity of the peripheral portion 44 is the same as that of the central portion 43, the pore diameter of the peripheral portion 44 is smaller than that of the central portion 43.

[0079] The flow resistance of the peripheral portion 44 differs from that of the central portion 43. In this embodiment, the flow resistance of the peripheral portion 44 is greater than that of the central portion 43. The flow resistance of the peripheral portion 44 is set to be different from that of the central portion 43 when forming the porous component 41. Because the flow resistance of the peripheral portion 44 is greater than that of the central portion 43, resin 42A is difficult to flow over the peripheral portion 44 and into the central portion 43 during insert molding of the fan component 40. Regarding the flow resistance of the peripheral portion 44, it is also possible that during insert molding, when the porous component 41 is compressed by the mold 50, the pores are compressed, the porosity decreases, and thus the flow resistance of the peripheral portion 44 is greater than that of the central portion 43 (see reference). Figure 6 ).

[0080] like Figure 3As shown, the porous component 41 has a pore-filled portion 45. At the pore-filled portion 45, a plurality of pores in the porous component 41 are filled with resin 42A. The pore-filled portion 45 is formed by impregnating the pores of the porous component 41 with resin 42A during the insert molding of the fan component 40. The porous component 41 is connected to the resin component 42 via the pore-filled portion 45. The pore-filled portion 45 is located around the central portion 43. The pore-filled portion 45 may also overlap with the peripheral portion 44.

[0081] <Manufacturing Method of Fan Components>

[0082] like Figures 3 to 6 As shown, the manufacturing method is a method for manufacturing a fan component 40, which includes: a porous component 41 having multiple pores; and a resin component 42 integrally molded with the porous component 41. The manufacturing method includes a step of insert molding the porous component 41 using resin 42A with a melt flow rate (MFR) of 2 g / 10 min or more and 45 g / 10 min or less. The fan component 40 is formed, for example, by insert molding. Figure 5 and Figure 6 In the figure, the right side corresponds to the hub 31 side in the direction of the rotation radius of the blade 32. The left side corresponds to the outer end side in the direction of the rotation radius of the blade 32. The manufacturing method includes a first process, a second process, and a third process.

[0083] The first process is the process of assembling porous components 41 in mold 50. Figure 5 This indicates that the porous component 41 is positioned in the mold 50 during the first process. A pin 52 is provided in the mold 50, inserted into the hole 51. During the first process, the pin 52 is positioned to protrude from the hole 51. The porous component 41 is positioned in contact with the pin 52 in the mold 50.

[0084] The second step is to press the porous component 41 using the mold 50. In this second step, the porous component 41 is compressed by the mold 50 in the thickness direction, so that the thickness of the porous component 41 is reduced from the first dimension W1 to the second dimension W2. The amount of compression of the porous component 41 is set, for example, based on the flow resistance of the compressed porous component 41.

[0085] The third process is the insertion molding of the porous component 41 using resin 42A. For example... Figure 6 As shown by the arrow in the image, from Figure 6 Resin 42A is injected into the mold 50 from the right side. During the resin injection process, the movement of the porous component 41 is inhibited by the pin 52. When the resin 42A fills the mold 50, the pin 52 is pressed into the hole 51 by the pressure of the resin 42A. A trace 52A of the pin 52 may also remain on the resin component 42 after the insert is molded (see reference). Figure 3 If the porous component 41 can be positioned in the mold 50 in a manner that prevents the porous component 41 from moving relative to the mold 50 during insert molding, the hole 51 and pin 52 can also be omitted from the mold 50.

[0086] Noise reduction effect of porous components

[0087] The noise reduction effect of the fan component 40 is achieved by configuring the porous component 41 so that the airflow KR passes through the pores of the porous component 41. If the pores of the porous component 41 are too small, or if the porosity of the porous component 41 is too low, the airflow KR cannot pass through the pores of the porous component 41, and therefore a sufficient noise reduction effect cannot be obtained. If the pores of the porous component 41 are large, or if the porosity of the porous component 41 is large, the amount of airflow KR passing through the pores of the porous component 41 increases. If the amount of airflow KR passing through the pores of the porous component 41 increases, the original pressure boosting effect of the fan 30 may not be achieved. In order to maintain not only a sufficient noise reduction effect but also the original pressure boosting effect of the fan 30, the flow resistance of the porous component 41 is set according to the pore diameter and porosity of the porous component 41.

[0088] exist Figure 7 In this context, the flow resistance value of the porous component 41 is mapped relative to the pore diameter and porosity of the porous component 41. Figure 7 In the diagram, the line representing a flow resistance of 0.2 kPa is represented by a dashed line. In regions where the flow resistance of the porous component 41 is 0.2 kPa or higher, resin 42A is difficult to flow into the porous component 41 during insert molding. In these regions, not only is resin 42A difficult to flow into the porous component 41 during insert molding, but the fan 30 also achieves a suitable pressure boosting effect.

[0089] exist Figure 8 In this context, the noise reduction effect of the porous component 41 relative to its pore size and porosity is mapped. The noise reduction effect is, for example, the sound pressure level that the porous component 41 can reduce. In regions where the pore size of the porous component 41 is 50 μm or more and 500 μm or less, and the porosity of the porous component 41 is 20% or more and 90% or less, the porous component 41 can maintain its noise reduction effect. Furthermore, the noise reduction effect in a fan 30 of the same shape is quantified as the noise level of the fan 30 with the porous component 41 relative to the noise level of the fan 30 without the porous component 41.

[0090] exist Figure 8In the diagram, the regions where the flow resistance is 0.2 kPa or higher, the pore size of the porous component 41 is 50 μm or higher and 500 μm or lower, and the porosity of the porous component 41 is 20% or higher and 90% or lower are indicated by double-dotted lines. In the regions indicated by double-dotted lines, not only can the noise reduction effect be maintained, but the fan 30 can also achieve an appropriate pressure boost effect.

[0091] exist Figure 9 The diagram shows the noise reduction effect of the fan component 40 relative to the MFR of the resin 42A constituting the resin component 42 when the flow resistance of the porous component 41 is 0.4 kPa, 0.5 kPa, 0.8 kPa, and 1.1 kPa. To obtain... Figure 9 Based on the data, multiple test fans 30 were fabricated. Specifically, multiple test fans 30 were constructed using fan components 40 with different flow resistances of porous components 41 and different MFRs of resin 42A constituting resin components 42. The multiple test fans 30 were identical in shape. The porous components 41 of the fan components 40 constituting the multiple test fans 30 were made of the same material but with different flow resistances. The resin components 42 of the fan components 40 constituting the multiple test fans 30 were made of the same resin 42A with different MFRs. The porous components 41 of the fan components 40 constituting the multiple test fans 30 were made of glass fiber reinforced styrene-acrylonitrile resin (ASG) foam. The resin components 42 of the fan components 40 constituting the multiple test fans 30 were made of glass fiber reinforced styrene-acrylonitrile resin (ASG). The noise level of the multiple test fans 30 was measured when they rotated. Figure 9 The data.

[0092] Figure 9 The noise reduction effect ratio is the ratio of the noise reduction effect of the test fan 30 to the maximum noise reduction effect of the test fan 30 under various values ​​of the MFR of resin 42A, with the flow resistance of porous component 41 at a specified value. Figure 9 With a flow resistance of 1.1 kPa for the porous component 41, the noise reduction effect reaches its maximum when the MFR of resin 42A is 25 g / 10 min. With a flow resistance of 1.1 kPa for the porous component 41, the fan 30 achieves a noise reduction effect of approximately 80% or more of the maximum value when the MFR of resin 42A is 35 g / 10 min.

[0093] The higher the MFR of resin 42A, the easier it is for resin 42A to flow into the through holes of porous component 41 during insert molding, thus tending to reduce the noise reduction effect of fan component 40. In addition, in areas where the flow resistance of porous component 41 is high and the MFR of resin 42A is low, it is difficult to form fan 30, thus the noise reduction effect of fan component 40 may be deviated.

[0094] When the flow resistance of the porous component 41 is 0.4 kPa or more and 0.8 kPa or less, and the MFR of the resin 42A is 2 g / 10 min or more and 45 g / 10 min or less, the fan component 40 can achieve a noise reduction effect. Furthermore, when the flow resistance of the porous component 41 is 0.4 kPa or more and 1.1 kPa or less, and the MFR of the resin 42A is 5 g / 10 min or more and 40 g / 10 min or less, the fan component 40 can achieve a noise reduction effect of 20% or more of the maximum noise reduction effect. Preferably, when the flow resistance of the porous component 41 is 0.5 kPa or more and 1.1 kPa or less, and the MFR of the resin 42A is 5 g / 10 min or more and 40 g / 10 min or less, the fan component 40 can achieve a noise reduction effect of 30% or more of the maximum noise reduction effect.

[0095] <The Role of the Implementation Method>

[0096] The function of this embodiment will be explained.

[0097] In this embodiment, the fan component 40 includes a resin component 42, which is formed of resin 42A with an MFR of 2 g / 10 min or more and 45 g / 10 min or less. Resin 42A with an MFR of 45 g / 10 min or less is less likely to flow into the pores of the porous component 41 during insert molding based on resin 42A.

[0098] In one example of the fan component 40 of this embodiment, the flow resistance of the porous component 41 is 0.5 kPa or more and 1.1 kPa or less. Figure 7 In the diagram, dashed lines represent the cases where the flow resistance is 0.5 kPa and 1.1 kPa. Figure 7In the diagram, the range of flow resistance from 0.5 kPa to 1.1 kPa is represented by the area between the dashed lines. By making the flow resistance 1.1 kPa or less, resin 42A can flow within the porous component 41 when it is used for insert molding. Therefore, the porous component 41 and the resin component 42 can be properly bonded in the fan component 40. On the other hand, by making the flow resistance 0.5 kPa or more, the porous structure of the porous component 41 is maintained to a degree that allows the fan component 40 to achieve a noise reduction effect based on the porous structure when it is used for insert molding.

[0099] The porous component 41 of this embodiment has the following flow resistance: the pore size of the porous component 41 is 50 μm or more and 500 μm or less, and the porosity of the porous component 41 is 20% or more and 90% or less. Because the flow resistance of the porous component 41 is sufficiently high, the resin 42A is difficult to flow within the porous component 41. Regarding the fan component 40, not only can sufficient noise reduction be maintained, but the resin 42A is also difficult to flow into the pores of the porous component 41 during insert molding.

[0100] The porous component 41 of this embodiment has a peripheral portion 44. During insert molding of the fan component 40, resin 42A first flows into the peripheral portion 44 and then flows towards the central portion 43 via the peripheral portion 44. The peripheral portion 44 of this embodiment has a width D1, thus preventing resin 42A from flowing into the central portion 43. By allowing resin 42A to flow into the peripheral portion 44, a pore-filled portion 45 is formed in the porous component 41. At the pore-filled portion 45, resin 42A flows into the pores, thus the porous component 41 and the resin component 42 are properly bonded through the pore-filled portion 45.

[0101] <Effects of the Implementation Method>

[0102] The effects of this implementation method will be explained.

[0103] (1) The fan component 40 includes a porous component 41 and a resin component 42. The resin 42A constituting the resin component 42 has an MFR of 2 g / 10 min or more and 45 g / 10 min or less. A portion of the pores of the porous component 41 are filled with resin 42A.

[0104] According to this structure, since the MFR of resin 42A is less than 45g / 10min, the number of pores filled with resin 42A in the porous component 41 can be reduced. Therefore, the porous component 41 and the resin component 42 can be properly integrally molded while maintaining the noise reduction effect of the porous component 41.

[0105] When resin 42A has an MFR of 45 g / 10 min or less, it is difficult for resin 42A to flow into the pores of porous component 41 when resin component 42 is integrally molded with porous component 41. Since resin 42A is difficult to flow into the pores of porous component 41, the pores of porous component 41 are easily maintained.

[0106] When the MFR of resin 42A is greater than 45 g / 10 min, resin 42A flows easily relative to the mold 50, thus shortening the injection time during insert molding. However, when the MFR of resin 42A is too large, during insert molding, resin 42A flows not only into the peripheral portion 44 of the porous component 41 but also into the central portion 43 of the porous component 41. If resin 42A flows into the central portion 43 of the porous component 41, it fills the pores in the central portion 43, thus reducing the number of pores in the porous component 41. Since the number of pores in the porous component 41 is reduced, the noise reduction effect based on the porous component 41 may be reduced. If the MFR of resin 42A is less than 45 g / 10 min, it is possible to prevent resin 42A from penetrating into the central portion 43 of the porous component 41 during insert molding.

[0107] The MFR of resin 42A can be above 2 g / 10 min and below 40 g / 10 min. Based on this structure, resin 42A is less likely to flow into the pores of the porous component 41, thus the pores of the porous component 41 are more easily maintained.

[0108] The MFR of resin 42A can be above 2 g / 10 min and below 35 g / 10 min. Based on this structure, resin 42A is less likely to flow into the pores of the porous component 41, thus the pores of the porous component 41 are more easily maintained.

[0109] When the MFR of resin 42A is less than 2 g / 10 min, resin 42A has difficulty flowing within the mold 50 during insert molding, making it difficult to form the fan component 40. If the MFR of resin 42A is too small, it becomes even more difficult to form the fan component 40 when the wall of the fan component 40 is made thinner. If the MFR of resin 42A is 2 g / 10 min or more, resin 42A can flow appropriately within the mold 50 during insert molding, thus enabling the proper formation of the fan component 40.

[0110] The MFR of resin 42A can be more than 5 g / 10 min and less than 45 g / 10 min. According to this structure, resin 42A can flow more properly in the mold 50 during insert molding, thus enabling more proper formation of the fan component 40.

[0111] Furthermore, based on this structure, the pores in the porous component 41 that are filled with resin 42A can be appropriately configured. By configuring the MFR in this way, the bonding strength between the porous component 41 and the resin component 42 can be improved while maintaining the noise reduction effect brought about by the porous structure of the porous component 41.

[0112] (2) The MFR of resin 42A is 5 g / 10 min or more and 40 g / 10 min or less. According to this structure, since the MFR of resin 42A is 40 g / 10 min or less, the pores of the filled resin 42A in the porous component 41 can be further reduced. Furthermore, if the MFR of resin 42A is 5 g / 10 min or more, resin 42A can flow appropriately within the mold 50 during insert molding, thus allowing for more appropriate formation of the fan component 40.

[0113] (3) The MFR of resin 42A is 5 g / 10 min or more and 35 g / 10 min or less. According to this structure, since the MFR of resin 42A is 35 g / 10 min or less, the pores of the filled resin 42A in the porous component 41 can be further reduced. Furthermore, if the MFR of resin 42A is 5 g / 10 min or more, resin 42A can flow appropriately within the mold 50 during insert molding, thus allowing for more appropriate formation of the fan component 40.

[0114] (4) The flow resistance of the porous component 41 is 0.5 kPa or more and 1.1 kPa or less. According to this structure, since the flow resistance of the porous component 41 is 0.5 kPa or more, the pores of the filled resin 42A in the porous component 41 can be further reduced. On the other hand, since the flow resistance of the porous component 41 is 1.1 kPa or less, the resin 42A can fill the pores of the porous component 41 to the extent that the porous component 41 and the resin component 42 are integrally formed. Thus, in the fan component 40, since the flow resistance of the porous component 41 is 0.5 kPa or more and 1.1 kPa or less, the noise reduction effect brought about by the porous structure can be maintained while molding the porous component 41 and the resin component 42 into one piece.

[0115] (5) The porosity of the porous component 41 is 20% or more and 90% or less, and the pore size of the porous component 41 is 50 μm or more and 500 μm or less. According to this structure, since the porosity of the porous component 41 is 20% or more and 90% or less, and the pore size of the porous component 41 is 50 μm or more and 500 μm or less, the pores of the filled resin 42A in the porous component 41 can be further reduced.

[0116] By increasing the flow resistance of the porous component 41, it becomes difficult for resin 42A to flow into the porous component 41. Since resin 42A is difficult to flow into the porous component 41, it is also difficult for resin 42A to flow into the pores of the porous component 41. By reducing the porosity and pore size by increasing the flow resistance of the porous component 41, it is easier to maintain the pores of the porous component 41 when it is integrally molded with the resin component 42. A porous component 41 with a porosity of 20% or more and 90% or less, and a pore size of 50 μm or more and 500 μm or less, not only maintains the noise reduction effect but also maintains the flow resistance that makes it difficult for resin 42A to flow into the pores of the porous component 41.

[0117] When the pore size of the porous component 41 is less than 50 μm, the noise reduction effect based on the porous component 41 decreases. When the pore size of the porous component 41 is greater than 500 μm, the flow resistance of the porous component 41 decreases, so resin 42A easily flows into the pores of the porous component 41 during insert molding. When the porosity of the porous component 41 is less than 20%, the noise reduction effect based on the porous component 41 decreases. When the porosity of the porous component 41 is greater than 90%, the flow resistance of the porous component 41 decreases, so resin 42A easily flows into the pores of the porous component 41 during insert molding.

[0118] (6) The porosity of the porous component 41 is 30% or more and 90% or less, and the pore size of the porous component 41 is 90 μm or more and 300 μm or less. According to this structure, since the porosity of the porous component 41 is 30% or more and 90% or less, and the pore size of the porous component 41 is 90 μm or more and 300 μm or less, the pores of the filled resin 42A in the porous component 41 can be further reduced.

[0119] (7) The porous component 41 has a pore-filled portion 45. At the pore-filled portion 45, the pores of the porous component 41 are filled with resin 42A. According to this structure, in the pore-filled portion 45, the multiple pores of the porous component 41 are filled with resin 42A, so that the porous component 41 can be properly bonded to the resin component 42 at the pore-filled portion 45.

[0120] (8) The porous component 41 has a central portion 43 and a peripheral portion 44. The flow resistance of the peripheral portion 44 is different from that of the central portion 43. According to this structure, in the porous component 41, by making the flow resistance of the central portion 43 different from that of the peripheral portion 44, the bonding between the porous component 41 and the resin component 42 can be properly operated. In this embodiment, by making the flow resistance of the peripheral portion 44 greater than that of the central portion 43, the porous component 41 and the resin component 42 can be operated in a manner where the bonding between them is only at the peripheral portion 44.

[0121] (9) The fan component 40 includes a porous component 41 and a resin component 42 integrally formed with the porous component 41. The porosity of the porous component 41 is 20% or more and 90% or less, and the pore size of the porous component 41 is 50 μm or more and 500 μm or less. According to this structure, since the porosity of the porous component 41 is 20% or more and 90% or less, and the pore size of the porous component 41 is 50 μm or more and 500 μm or less, the pores of the filled resin 42A in the porous component 41 can be reduced. Therefore, the porous component 41 and the resin component 42 can be properly integrally formed while maintaining the noise reduction effect of the porous component 41.

[0122] (10) The fan 30 is composed of a fan component 40. According to this structure, it is possible to provide a fan 30 composed of a fan component 40.

[0123] (11) The fan unit 20 includes a fan 30 and a flare 21. According to this structure, a fan unit 20 including a fan 30 and a flare 21 can be provided.

[0124] (12) The air conditioner 10A includes a fan unit 20. Based on this structure, it is possible to provide an air conditioner 10A that includes a fan unit 20.

[0125] (13) The method for manufacturing the fan component 40 includes a step of insert molding a porous component 41 having multiple pores using resin 42A with an MFR of 2 g / 10 min or more and 45 g / 10 min or less. According to this structure, since the MFR of resin 42A is 2 g / 10 min or more and 45 g / 10 min or less, it is difficult for resin 42A to flow into the pores of the porous component 41 during insert molding. Because resin 42A is difficult to flow into the pores of the porous component 41, the pores of the porous component 41 are easily maintained. By using a resin component 42 with such an MFR, the porous component 41 can be properly inserted while maintaining its noise reduction effect.

[0126] <Variation Example>

[0127] Regarding the air conditioner, fan unit, fan, fan component, and method for manufacturing the fan component disclosed herein, in addition to the embodiments described above, it may also be a combination of the following modified examples and at least two mutually consistent modified examples.

[0128] • Air conditioner 10A can also be an air purifier. Fan unit 20 can also serve as the intake or exhaust port of an air purifier. An air purifier, for example, treats the intake air using filters, UV devices, ion generators, virus-removing devices, and flow filters before blowing it out. The air purifier is configured to treat the air in indoor spaces such as homes and offices. It can also be configured to treat the air in indoor spaces such as warehouses for storing goods or work areas for processing goods.

[0129] The fan unit 20 can also be installed in the heat pump device. The heat pump device of this modification includes the fan unit 20. The heat pump device is, for example, a device with a refrigerant circuit. The heat pump device is, for example, an air conditioner or a water heater. According to this structure, a heat pump device with the fan unit 20 can be provided.

[0130] The components constituted by the fan component 40 are not limited to the fan 30. The flare 21 may also be constituted by the fan component 40, and the fan housing 23 may also be constituted by the fan component 40. When the fan housing 23 is constituted by the fan component 40, the blowout 23A or the support 23B may also be constituted by the fan component 40.

[0131] • The specified conditions may also be test conditions based on ISO 1133-1 or ISO 1133-2. The specified conditions may also be test conditions based on JIS K7210-1, JIS K7210-2 or ASTM D1238.

[0132] • MFR can also be called melt volume-flow rate (MVR). For example, MVR is the product of the melt mass flow rate of resin 42A and the melting density of resin 42A.

[0133] • The flow resistance of the peripheral portion 44 can also be less than that of the central portion 43. According to this structure, the resin 42A can easily penetrate into the peripheral portion 44, thus improving the bonding strength between the porous component 41 and the resin component 42.

[0134] The following technologies are disclosed in this specification.

[0135] (C1) A fan component (40) comprising a porous component (41) and a resin component (42) integrally formed with the porous component (41), wherein the porous component (41) has a central portion (43) and a peripheral portion (44) surrounding the central portion (43). The flow resistance of the peripheral portion (44) is different from the flow resistance of the central portion (43).

[0136] (C2) In the fan component (40) described in (C1), the porosity of the porous component (41) is 20% or more and 90% or less, and the pore diameter of the porous component (41) is 50 μm or more and 500 μm or less.

[0137] The embodiments and variations of the fan component, fan, fan unit, air conditioner, heat pump device, and manufacturing method of the fan component have been described above. However, it should be understood that various changes in manner and detailed structure can be made without departing from the spirit and scope of the manufacturing method of the fan component, fan, fan unit, air conditioner, heat pump device, and manufacturing method of the fan component as described in the claims.

[0138] Label Explanation

[0139] 10A: Air conditioner; 10: Outdoor unit; 20: Fan unit; 21: Flare; 30: Fan; 40: Fan component; 41: Porous component; 42: Resin component; 42A: Resin; 43: Central part; 44: Peripheral part; 45: Hole filling part.

Claims

1. A fan component (40) comprising: a porous component (41) having a plurality of pores; and a resin component (42) integrally formed with the porous component (41), wherein, The porous component (41) has a through hole that extends through the fan component (40) in the thickness direction. The melt flow rate (MFR) of the resin (42A) constituting the resin component (42) is 5 g / 10 min or more and 40 g / 10 min or less. The flow resistance of the porous component (41) is above 0.5 kPa and below 1.1 kPa. The resin (42A) is filled in a portion of the plurality of pores.

2. The fan component according to claim 1, wherein, The melt flow rate (MFR) of the resin (42A) is 5 g / 10 min or more and 35 g / 10 min or less.

3. The fan component according to claim 1, wherein, The porosity of the porous component (41) is 20% or more and 90% or less. The porous component (41) has a pore size of 50 μm or more and 500 μm or less.

4. The fan component according to claim 3, wherein, The porosity of the porous component (41) is 30% or more and 90% or less. The porous component (41) has a pore size of 90 μm or more and 300 μm or less.

5. The fan component according to claim 1, wherein, The porous component (41) has a pore-filling portion (45). At the pore-filled portion (45), the plurality of pores of the porous component (41) are filled by the resin (42A).

6. The fan component according to claim 1, wherein, The porous component (41) has a central portion (43) and a peripheral portion (44) located around the central portion (43). The flow resistance of the peripheral portion (44) is different from that of the central portion (43).

7. A fan component (40) comprising: a porous component (41) having a plurality of pores; and a resin component (42) integrally formed with the porous component (41), wherein, The melt flow rate (MFR) of the resin (42A) constituting the resin component (42) is 2 g / 10 min or more and 45 g / 10 min or less. The porous component (41) has a central portion (43) and a peripheral portion (44) located around the central portion (43). The flow resistance of the peripheral portion (44) is different from the flow resistance of the central portion (43). The resin (42A) is filled in a portion of the plurality of pores.

8. A fan component (40) comprising: a porous component (41); and a resin component (42) integrally formed with the porous component (41), wherein, The porous component (41) has a through hole that extends through the fan component (40) in the thickness direction. The porosity of the porous component (41) is 20% or more and 90% or less. The porous component (41) has a pore size of 50 μm or more and 500 μm or less. The melt flow rate (MFR) of the resin (42A) constituting the resin component (42) is 5 g / 10 min or more and 40 g / 10 min or less. The flow resistance of the porous component (41) is above 0.5 kPa and below 1.1 kPa.

9. A fan, wherein, The fan is composed of the fan component (40) as described in any one of claims 1 to 8.

10. A fan unit, wherein, The fan unit includes: The fan (30) as described in claim 9; and Trumpet mouth (21).

11. An air conditioner, wherein, The air conditioner includes the fan unit (20) as described in claim 10.

12. A heat pump device, wherein, The heat pump device includes the fan unit (20) as described in claim 10.

13. A method for manufacturing a fan component (40), the fan component (40) comprising: a porous component (41) having a plurality of pores; and a resin component (42) integrally formed with the porous component (41), wherein, The porous component (41) has a through hole that extends through the fan component (40) in the thickness direction. The manufacturing method of the fan component (40) includes the following steps: insert molding the porous component (41) with a resin (42A) having a melt flow rate (MFR) of 5 g / 10 min or more and 40 g / 10 min or less. The flow resistance of the porous component (41) is above 0.5 kPa and below 1.1 kPa.