The present disclosure relates to a seat pad and a seat pad manufacturing method.
There are seat pads in which a part of a surface is a smooth portion with a surface roughness of 2 to 20 μm, and the air permeability of a surface portion of the smooth portion is restrained to a low level (refer to, for example, Patent Literature (PTL) 1). Such seat pads serve to provide sufficiently low vibration transmissibility and excellent vibration absorptivity, owing to the low air permeability of the surface portion.
However, there is a concern that the above-described seat pads may become stuffy due to heat buildup when the seat pads are kept seated for a long time. In other words, there is room for improvement with respect to the above-described seat pads in terms of improving thermal comfort while improving the vibration absorptivity.
It would be helpful to provide a seat pad with improved thermal comfort and improved vibration absorptivity, and a seat pad manufacturing method for easily obtaining the seat pad.
A seat pad according to the present disclosure includes a surface portion up to 10 mm from a surface, wherein when the surface portion is cut out and the air permeability of the surface portion is measured in compliance with JIS K 6400, the air permeability is more than 5 cc/cm2/sec and 25 cc/cm2/sec or less.
In the seat pad according to the present disclosure, when a core portion inside the surface portion is cut out and the air permeability of the core portion is measured in compliance with JIS K 6400, the air permeability of the core portion is preferably greater than the air permeability of the surface portion.
The seat pad according to the present disclosure may further include a cushion pad,
The seat pad according to the present disclosure may further include a cushion pad,
In the seat pad according to the present disclosure, the air permeability of the surface portion of an entire surface of the cushion pad may be limited to within the range stated in claim 1.
The seat pad according to the present disclosure may further include a groove configured to partition an air permeability limited portion having the surface portion the air permeability of which is limited to within a range stated in claim 1 from another portion adjacent to the air permeability limited portion,
A seat pad manufacturing method according to the present disclosure is a seat pad manufacturing method for obtaining each of the seat pads described above, the seat pad manufacturing method including supplying a molding material into a molding die and performing foam molding,
In the seat pad manufacturing method according to the present disclosure, the molding die is a molding die to obtain a cushion pad, and
In the seat pad manufacturing method according to the present disclosure, the molding die is a molding die to obtain a cushion pad, and
In the seat pad manufacturing method according to the present disclosure, as the molding die, a molding die the entire inner surface of which is covered with polystyrene or polyethylene may be used.
In the seat pad manufacturing method according to the present disclosure,
In the seat pad manufacturing method according to the present disclosure, as the molding die, a molding die the inner surface of which is covered with high-density polyethylene is preferably used.
In the seat pad manufacturing method according to the present disclosure, as the molding die, a molding die the inner surface of which is covered with polystyrene is preferably used.
In the seat pad manufacturing method according to the present disclosure, as the molding die, a molding die the inner surface of which is covered with low-density polyethylene is preferably used.
According to the present disclosure, it is possible to provide the seat pad with improved thermal comfort and improved vibration absorptivity, and the seat pad manufacturing method for easily obtaining the seat pad.
In the accompanying drawings:
Seat pads and a seat pad manufacturing method according to embodiments of the present disclosure will be described below with reference to the drawings.
[Seat Pad]
In the example of
The seat pad 1 is composed of a resin foam. The resin foam is preferably a soft resin foam, and more preferably a soft polyurethane foam. In this embodiment, the cushion pad 1a and the back pad 1b are configured separately from each other. However, the cushion pad 1a and the back pad 1b may be formed integrally.
With reference to
In
According to the present disclosure, the surface portion 2 may be a surface portion cut out of a particular surface 1f of the seat pad 1, out of the entire surface 1f of the seat pad 1 including the cushion pad 1a and the back pad 1b. However, according to the present disclosure, as illustrated in
With reference to
In general, when the air permeability of the resin foam is reduced, vibration absorptivity becomes better, and vibration transmissibility becomes lower. However, when the air permeability is reduced, there is a concern that heat buildup causes stuffiness and other problems.
In contrast,
With reference to
On the other hand, with reference to
Also, according to this embodiment, when the core portion 3 inside the surface portion 2 is cut out and the air permeability AR2 of the core portion 3 (hereinafter also referred to as “core air permeability AR2”) is measured in compliance with JIS K 6400, it is preferable that the air permeability AR2 is greater than the air permeability AR1 of the surface portion 2. In this case, heat transmitted through the surface portion 2 is efficiently released to the core portion 3, thereby further improving thermal comfort.
According to the present disclosure, the air permeability AR2 of the core portion 3 may be equal to or greater than the surface air permeability AR1. In this case, air-damping effect is increased, which further improves vibration absorptivity.
As described above, according to the present disclosure, the surface portion 2 of the entire surface 1f of the seat pad 1 may be designed as the air permeability limited surface portion 2a, and the surface air permeability AR1 of the entire surface 1f of the seat pad 1 may be limited to within a range of 5 cc/cm2/sec<AR1≤25 cc/cm2/sec. With reference to
On the other hand, in a seat pad, there is a trade-off between air permeability and vibration absorptivity. Therefore, if the air permeability is made comfortable from part to part of the seat pad, the performance of the seat pad as a whole can be further improved.
According to the present disclosure, the surface portion 2 at any position of the surface 1f of the cushion pad 1a may be designed as the air permeability limited surface portion 2a, and the surface air permeability AR1 of the surface 1f of the seat pad 1 may be locally limited to within the range of 5 cc/cm2/sec<AR1≤25 cc/cm2/sec.
With reference to
With reference to
In addition, the seat pad of the present disclosure may have a groove 30 that partitions between an air permeability limited portion having a surface portion 2 the surface air permeability AR1 of which is limited within a range of 5 cc/cm2/sec<AR1≤25 cc/cm2/sec and another portion adjacent to the air permeability limited portion, and may include, in the surface portion 2 of the air permeability limited portion, a surface portion of a side face of the groove 30 connected to the air permeability limited portion.
With reference to
Deepening the groove depth of the groove 30 restrains airflow in the pad between the air permeability limited portion and other portions, thereby improving vibration absorptivity. For example, the groove depth of the groove 30 should be deeper than suspension grooves (grooves for fixing the surface skin 11 of the seat by wires and clips) that partition individual portions. As a specific groove depth, for example, the distance between the surface 1f of the seat pad 1 and the bottom of the groove should be 10 mm or less, and more preferably 5 mm or less. In this embodiment, the groove depths of the grooves 31, 32, and 33 are constant throughout the entire groove 30. Also, in this embodiment, the groove widths of the grooves 31, 32, and 33 are constant throughout the entire groove 30.
In the above second to fourth embodiments, a surface portion 2 of a back side surface 1f2 of the cushion pad 1a may be designed as an air permeability limited surface portion 2a having a surface air permeability AR1 of within a range of 5 cc/cm2/sec<AR1≤25 cc/cm2/sec, as in the first embodiment, but may have an air permeability outside this range.
[Seat Pad Manufacturing Method]
Next, a seat pad manufacturing method according to an embodiment will be described with reference to the drawings.
The seat pad manufacturing method according to the embodiment of the present disclosure is a seat pad manufacturing method for obtaining the seat pad 1 by supplying a molding material M1 into a molding die 100 and performing foam molding.
With reference to
Also, with reference to
The seat pad manufacturing method according to the embodiment of the present disclosure can be outlined as follows.
[Molding Die Placing Step]
First, as illustrated in
[Foam Molding Step]
Next, as illustrated in
[Die Opening Step]
After the foam molding inside the molding die 100 is completed, the molding die 100 is opened and separated into the upper die 101 and the lower die 102. Thereby, the seat pad 1 the surface 1f of which has a remaining percentage of the cell membranes of 92% or more can be obtained.
In this way, when the molding die 100 the inner surface 100f of which is covered with the resin M2 is used as the molding die 100, the seat pad 1 can be easily obtained by a simple procedure of just covering the inner surface 100f of the molding die 100 with the resin M2.
As described above, in the manufacturing method according to this embodiment, the molding die 100 the entire inner surface 100f of which is covered with the resin M2 is used.
On the other hand, according to the manufacturing method of the present disclosure, as the molding die 100, a molding die the inner surface of which on a seat side of the cushion pad 1a is locally covered with the resin M2 may be used.
As described above, in this embodiment, the molding die 100 is a molding die to obtain the cushion pad 1a. As illustrated in
In particular, as illustrated in
As described above, in this embodiment, a molding die 100 is a molding die to obtain the cushion pad 1a. As illustrated in
[Test Results]
Next, the following are test results for seat pads obtained by using different types of resin M2, as the resin M2 that covers the inner surface 100f of the molding die 100.
In
In
Next,
It is found from
In more detail, in the case of 25 cc/cm2/sec<AR1, the resonance magnification RM exceeds 4.5. This test result is consistent with the test results of two types of seat pads, i.e. the seat pad 20 as Comparative Example 1 in which foam molding was performed without covering the inner surface 100f of the molding die 100 with the resin M2, and the seat pad in which foam molding was performed with covering the inner surface 100f of the molding die 100 with PP (polypropylene) as the resin M2.
In contrast, in the case of AR1≤25 cc/cm2/sec, the resonance magnification RM is less than 4.5. This test result corresponds to the test results of three types of seat pads, i.e. the seat pad 1 (hereinafter also referred to as “HDPE molded seat pad 1”) according to this embodiment in which foam molding was performed with covering the inner surface 100f of the molding die 100 with HDPE (high-density polyethylene) as the resin M2, the seat pad 1 (hereinafter also referred to as “LDPE molded seat pad 1”) according to this embodiment in which foam molding was performed with covering the inner surface 100f of the molding die 100 with LDPE (low-density polyethylene) as the resin M2, and the seat pad 1 (hereinafter also referred to as “PS molded seat pad 1”) according to this embodiment in which foam molding was performed with covering the inner surface 100f of the molding die 100 with PS (polystyrene) as the resin M2.
Also, it is found from
In more detail, according to the two types of seat pads, i.e. the HDPE molded seat pad 1 according to this embodiment and the PS molded seat pad 1 according to another embodiment of the present disclosure, the resonance magnification RM is restrained at 3.0 to 3.5, in the vicinity of AR1=5 cc/cm2/sec. Also, in the LDPE molded seat pad 1 according to this embodiment, the resonance magnification VR is sometimes restrained at 3.0 to 3.5, in the vicinity of AR1=5 cc/cm2/sec. In particular, in the case of the HDPE molded seat pad 1 according to this embodiment, the resonance magnification RM is restrained most at around 3.0.
As is apparent from the above test results, the seat pad manufacturing method according to the present disclosure preferably uses the molding die 100 in which the inner surface 100f of the molding die 100 is covered with high-density polyethylene. In this case, the resonance magnification RM of the seat pad 1 can be most effectively reduced. Therefore, in this case, the vibration absorptivity is further improved.
In addition, as is apparent from the above test results, the seat pad manufacturing method according to the present disclosure preferably uses, as the molding die 100, a molding die 100 the inner surface 100f of which is covered with polystyrene. Also in this case, the resonant magnification RM of the seat pad can be reduced effectively, as in the case of using the molding die 100 the inner surface 100f of which is covered with high-density polyethylene. Therefore, in this case, the vibration absorptivity is further improved. In particular, when a molding die covered with HDPE is used, the resonance magnification RM is further reduced, in other words, the vibration absorptivity is further improved.
In addition, as is apparent from the above test results, the seat pad manufacturing method according to the present disclosure preferably uses, as the molding die 100, a molding die 100 the inner surface 100f of which is covered with low-density polyethylene. Also in this case, the vibration absorptivity is further improved.
The following table indicates the resonance frequency, resonance magnification, and surface air permeability of each of the seat pads obtained by foam molding using the molding die 100 the inner surface 100f of which is covered with the resin M2, together with a remaining membrane ratio (%). PP-1 and PP-2 each represent polypropylene. Normal indicates a case in which foam molding is performed without covering the inner surface 10f of the molding die 100 with the resin M2. In other words, Normal indicates the seat pad 20 of Comparative Example 1. The remaining membrane ratio (%) is, in the surface 1f of the seat pad 1, the remaining ratio of the cell membrane 5 to a predetermined area of the surface 1f. Here, the predetermined area is a square area of 80 mm in length×80 mm in width.
With reference to Table 1 above, it is found that, in the manufacturing method of the seat pad 1, when high-density polyethylene is used as the resin M2 to cover the inner surface 100f of the molding die 100, the remaining ratio of the cell membrane is 97.5% or more and the surface air permeability AR1 satisfies 5 cc/cm2/sec<AR1≤25 cc/cm2/sec. It can also be found that the surface air permeability AR1 is restrained, as compared to the case of using polypropylene or low-density polyethylene as the resin M2 to cover the inner surface 100f of the molding die 100. In other words, when high-density polyethylene is used as the resin M2 to cover the inner surface 100f of the molding die 100, air-damping effect, i.e. vibration absorptivity becomes the best.
Also, with reference to Table 1 above, it is found that, in the manufacturing method of the seat pad 1, when polystyrene is used as the resin M2 to cover the inner surface 100f of the molding die 100, the remaining ratio of the cell membrane is 97.5% or more, as in the case of using high-density polyethylene, and the surface air permeability AR1 satisfies 5 cc/cm2/sec<AR1≤25 cc/cm2/sec. Therefore, in this case too, vibration absorptivity becomes the best.
Also, with reference to Table 1 above, it is found that, in the manufacturing method of the seat pad 1, when low-density polyethylene is used as the resin M2 to cover the inner surface 100f of the molding die 100, the remaining ratio of the cell membrane is 95% or more and the surface air permeability AR1 satisfies 5 cc/cm2/sec<AR1≤25 cc/cm2/sec. It can also be found that the surface air permeability AR1 is restrained, as compared to the case of using polypropylene as the resin M2 to cover the inner surface 100f of the molding die 100. In other words, the use of low-density polyethylene, as the resin M2 to cover the inner surface 100f of the molding die 100, results in better air-damping effect, i.e. better vibration absorptivity than the use of polypropylene.
The above describes exemplary embodiments of the present disclosure, and various modifications can be made without departing from the scope of the claims. In addition, the various configurations employed in each of the above-described embodiments can be mutually replaced as appropriate.
Number | Date | Country | Kind |
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2019-225322 | Dec 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/045740 | 12/8/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/117744 | 6/17/2021 | WO | A |
Number | Name | Date | Kind |
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10106064 | Kumagai et al. | Oct 2018 | B2 |
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Entry |
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Number | Date | Country | |
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20220369828 A1 | Nov 2022 | US |