TWM574453U - Quilt structure with non-powered energy layer - Google Patents

Abstract

A quilt structure with non-powered energy layer having an insulating layer, a first barrier layer, a second barrier layer, a first fabric layer and a second fabric layer is provide. The first barrier layer and the second barrier layer are disposed on two opposite sides of the insulating layer. The first fabric layer is disposed on one of the first barrier layer or the second barrier layer opposite the insulating layer, and the second fabric layer is disposed on another of the first barrier layer or the second barrier layer opposite the insulating layer. At least one of the insulating layer, first fabric layer and second fabric layer has far-infrared fibers.

Description

Enthalpy structure with non-powered energy layer

The present invention relates to a bedding structure having a non-powered energy layer, and more particularly to a bedding structure having a non-powered energy layer made of far-infrared fibers.

In bedding and medical bedding products, although many manufacturers claim that they have the function of radiating far-infrared rays, which can promote the blood circulation or body metabolism of users, but few manufacturers can put forward the actual Research or test data is a testament to the efficacy of these products.

What's more, Far Infrared (FIR) generally refers to infrared light with a wavelength of 5.6 to 1000 micrometers (μm), but in terms of efficacy, it has a far-infrared wavelength with a wavelength of 4 to 14 microns and is produced by human molecules. Resonance, which promotes microvascular expansion, smoothes blood circulation, and promotes optimal metabolism.

Some manufacturers in the workshops can arbitrarily fill in special fibers or powders that can radiate far-infrared wavelengths in bedding and medical bedding products without the basic principle of far-infrared rays, which not only fails to achieve the claimed effect, but is also likely to be over-absorbed. The radioactive energy actually causes physical discomfort.

In view of this, how to provide a bedding product (such as a bedding structure) that can accurately emit far-infrared rays with a wavelength of 4 to 14 microns, and prove the efficacy by actual research or test data to ensure the rights of consumers. It is an urgent problem to be solved by those skilled in the art.

An object of the present invention is to provide a bedding structure having a non-powered energy layer, wherein the first barrier layer and the second barrier layer are disposed on both sides of the thermal insulation layer to prevent material escaping inside the thermal insulation layer. Out or exposed.

Another object of the present invention is to provide a far-infrared fiber for forming a bedding structure having a non-powered energy layer, which can be woven on the insulating layer of the bedding structure, the first barrier layer, the second barrier layer, and the first cloth. At least one of the layer or the second cloth layer to achieve the effect of radiating far infrared rays during use.

To achieve the above object, a bedding structure having a non-powered energy layer provided by the present invention comprises a heat insulating layer, a first barrier layer, a second barrier layer, a first cloth layer and a second cloth layer. The first barrier layer and the second barrier layer are respectively disposed on opposite sides of the insulating layer. The first fabric layer is disposed on one of the first barrier layer or the second barrier layer, and the second fabric layer is disposed on the other of the first barrier layer or the second barrier layer. Wherein at least one of the warm layer, the first cloth layer and the second cloth layer comprises a far infrared fiber.

Preferably, the first fabric layer and the second fabric layer are a bristle fabric, a breathable fabric or a combination thereof.

Preferably, the first barrier layer and the second barrier layer are non-woven fabrics or fabrics containing a printing coating.

Preferably, the insulating layer is wool, silk, fiber cotton, cotton, down or a combination thereof.

Preferably, at least one of the first barrier layer or the second barrier layer is a textile having a metallic material.

Preferably, the metal material is disposed on at least one of the first barrier layer or the second barrier layer in a manner of being shaped into metal fibers.

Preferably, the metal material is disposed on at least one of the first barrier layer or the second barrier layer in a coating manner.

Preferably, the metal material is disposed on one side of the heat insulating layer.

In order to make the above objects, technical features and advantages more apparent, the following description will be described in detail with reference to the accompanying drawings.

The following is a detailed description of the specific embodiments of the present invention; however, the present invention may be practiced in various different forms without departing from the spirit of the invention, and the scope of the present invention should not be construed as being limited to the description. The presenter. In addition, the technical content of each embodiment in the above novel content may also be used as the technical content of the embodiment or as a possible variation of the embodiment.

Please refer to FIG. 1 , which is a perspective view of a bedding structure 100 having a non-powered energy layer. As shown in the figure, the bedding structure 100 is illustrated as a quilt in this embodiment, but is not limited thereto. In other words, the bedding structure 100 may also have a use state such as a mattress or a pad.

Please refer to the embodiment shown in FIG. 2 , wherein the bedding structure 100 includes a thermal insulation layer 110 , a first barrier layer 120 , a second barrier layer 130 , a first fabric layer 140 , and a second fabric layer 150 . The relationship between the components is further explained below.

First, in the present invention, the first barrier layer 120 and the second barrier layer 130 are respectively disposed on opposite sides of the thermal insulation layer 110, and the first fabric layer 140 is disposed on the first insulation layer 110. The barrier layer 120 or the second barrier layer 130 is disposed on one of the first barrier layer 120 or the second barrier layer 130. In other words, in the embodiment shown in FIG. 2, when the first cloth layer 140 and the second cloth layer 150 respectively cover the heat insulating layer 110 from the upper side and the lower side, the first barrier layer 120 and the second barrier layer 130 are suitable. They may be sandwiched between the first cloth layer 140 and the heat insulating layer 110, and between the heat insulating layer 110 and the second cloth layer 150, respectively. In addition, at least one layer of the insulating layer 110, the first cloth layer 140 or the second cloth layer 150 comprises a far-infrared fiber such that a specific layer having the far-infrared fiber 200 forms a non-powered energy layer. In other words, the particular layer having the far-infrared fiber 200 can achieve the effect of radiating far-infrared energy during use by a non-powered approach (ie, without additional power applied).

In addition, the first barrier layer 120 and the second barrier layer 130 in FIG. 2 may be exchanged, that is, as shown in the embodiment of FIG. 3, when the first fabric layer 140 and the second fabric layer 150 are respectively When the upper side and the lower side are covered with the heat insulating layer 110, the second barrier layer 130 is sandwiched between the upper first cloth layer 140 and the heat insulating layer 110, and the first barrier layer 120 is sandwiched between the lower heat insulating layer. 110 is between the second cloth layer 150.

Specifically, the insulation layer 110 of the present bedding structure 100 may include wool, silk, fiber cotton, cotton, down, or a combination thereof. When the thermal insulation layer 110 of the embodiment is exemplified by cotton, the Danny number of the cotton is preferably 1.5. As a result, since the cotton having a lower Danny number is used, the heat insulating layer 110 can increase the overall softness of the structure of the bedding structure 100 while maintaining the heat insulating effect.

In addition, the first cloth layer 140 and the second cloth layer 150 are a bristle cloth, a breathable cloth or a combination thereof, and the first barrier layer 120 and the second barrier layer 130 are non-woven fabrics or fabrics containing a printing paint.

In the present invention, at least one of the first barrier layer 120 or the second barrier layer 130 is a textile having a metal material 160; that is, the metal material 160 may have a shape formed into a metal fiber. A shape of at least one of the barrier layer 120 or the second barrier layer 130, or the metal material 160 may also have a configuration in which at least one of the first barrier layer 120 or the second barrier layer 130 is disposed in a coating manner.

For the use of the fabric layers, in a preferred embodiment of the present invention, the first fabric layer 140 can be made of a breathable fabric, and the second fabric layer 150 can be made of a bristle fabric. Thus, the bedding structure 100 of this embodiment. It can be used as a dual-use for summer cool and warm winter. In another embodiment, the first fabric layer 140 and the second fabric layer 150 of the bedding structure 100 can be made of a breathable fabric, and only used as a breathable cool quilt for summer use. In still another embodiment, the first cloth layer 140 and the second cloth layer 150 can be used as a winter warm cover and a warm mattress. In other words, regardless of whether the first fabric layer 140 and the second fabric layer 150 are of the same or different fabrics, the consumer can purchase according to different usage requirements.

For a portion of the first barrier layer 120 and the second barrier layer 130, in a preferred embodiment of the present invention, the first barrier layer 120 may be a non-woven fabric, and the second barrier layer 130 may have a metal material 160. Textiles. More specifically, please refer to Fig. 2, if the cotton with the lower Danny number of the insulation layer 110 has a relatively softer softness, the cotton fiber is finer, so the first is not laid. In the case of the barrier layer 120 and the second barrier layer 130, the cotton of the thermal insulation layer 110 will more easily escape from the gap of the first fabric layer 140 and/or the second fabric layer 150, so that the first barrier layer 120 is laid. After the second barrier layer 130, the non-woven fabric of the first barrier layer 120 and the textile of the second barrier layer 130 having the metal material 160 can effectively prevent the fine cotton fibers from being removed from the first fabric layer 140 and/or the second fabric layer. The phenomenon of escape from the gap of 150.

In the embodiment shown in FIG. 2, the metal material 160 of the second barrier layer 130 is disposed on the second barrier layer 130 in a coating manner, and the metal material 160 also has the effect of radiating far infrared rays, and the metal material The 160 is disposed on the second barrier layer 130 in such a manner as to face one side of the insulating layer 110. In detail, in the embodiment shown in FIG. 2, by placing the metal material 160 on one side of the second barrier layer 130 facing the heat insulating layer 110, even if the structure of the bedding structure 100 is long After use, the metal material 160 is detached, and part of the metal material 160 that is detached from the metal material 160 is not easily escaped by the slit of the second cloth layer 150, thereby affecting the user.

Further, in another aspect shown in FIG. 3, only the metal material 160 shown in FIG. 2 is changed by coating to one of the facing insulating layers 110 provided on the first barrier layer 120. On the side, the metal material 160 disposed in a coating manner also has no disadvantage of being exuded from the slit of the second cloth layer 150.

In the embodiment shown in FIG. 4, the metal material 160 is disposed in the second barrier layer 130 in the form of metal fibers. Therefore, the second barrier layer 130 is a blended fabric and becomes a blended fabric. The second barrier layer 130 will not have the shedding phenomenon of the metal material 160.

The foregoing metal material 160 includes metal particles of the following group: titanium (Ti), germanium (Ge), zinc (Zn), aluminum (Al), and magnesium (Mg).

With regard to the far-infrared ray function of the beryllium structure 100 of the present invention which is manufactured by using far-infrared fibers, the following tests (1), (2) and (3) have been disclosed.

First, the test method used in the test (1) is: during the test, the subject is measured for blood flow and blood flow after lying for 30 minutes in a state covered with the bedding structure 100 having far-infrared fibers. Speed and skin temperature, and the results are reported in Table 1.

Table 1:  <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td> Measurement Project</td><td> Measurement Results</td></tr> <tr><td> Abdomen</td><td> Waist</td><td> Shoulder </td></tr><tr><td> Blood Flow</td><td> Adaptation Period< /td><td> 36.6 </td><td> 60.0 </td><td> 37.9 </td></tr><tr><td> Test Period</td><td> 54.3 </td ><td> 73.0 </td><td> 49.0 </td></tr><tr><td> Rate of change (%) </td><td> 48.5 </td><td> 21.7 </ Td><td> 29.3 </td></tr><tr><td> blood flow rate</td><td> adaptation period</td><td> 9.0 </td><td> 12.0 </ Td><td> 7.8 </td></tr><tr><td> Test period</td><td> 13.5 </td><td> 14.0 </td><td> 8.8 </td> </tr><tr><td> Rate of change (%) </td><td> 50.0 </td><td> 16.7 </td><td> 12.9 </td></tr><tr> <td> Skin temperature (°C) </td><td> Adaptation period</td><td> 31.3 </td><td> 31.2 </td><td> 31.4 </td></tr>< Tr><td> test period</td><td> 33.3 </td><td> 32.6 </td><td> 33.5 </td></tr><tr><td> rate of change (%) </td><td> 2.0 </td><td> 1.4 </td><td> 2.1 </td></tr></TBODY></TABLE>

It can be seen from Table 1 that after the subject covered the bedding structure 100 of the present invention, the blood flow and blood flow rate of the abdomen, the waist and the shoulder were significantly increased, and the skin temperature did not change significantly, only slightly increased. This result shows that the use of the bedding structure 100 of the present invention can effectively improve blood circulation while raising the body surface temperature of the user and taking into consideration safety, and the blood pressure pulse is maintained normal.

The test method used in the test (2) is to compare the difference in the effect of the microcirculation of the diabetic patient (type 2) on the surface of the mattress with the bedding structure 100 of the present invention and the general mattress. The measurement position is the anterior tibial muscle of the shoulder and the largest leg. The subject was rested in a sitting position after coming to the clinical trial room, and the ambient room temperature was controlled at 23 ± 1 °C. First, measure the blood pressure and heartbeat of the subject. Next, the subject was asked to rest for 30 minutes in a lying position, and then the physiological data before covering the mattress was measured for 200 seconds. After the measurement, the test group covered the test subject with the test mattress, and the coating time was 20 minutes; the control group was coated with the general mattress, and then coated in the coated state. Measured for 200 seconds.

The experimental results show that for diabetic patients, the mattress with the bedding structure 100 of the present invention has 11%, 16% and 27% higher microcirculation blood flow in the shoulder, right leg and left leg, respectively. The results are shown in Table 2.

Table 2:

On the other hand, for diabetic patients, the mattress with the bedding structure 100 of the present invention has a body surface temperature rise of 0.9 ° C, 1.0 ° C and 0.9 ° C in the shoulder, right leg and left leg, respectively. The results are shown in Table 3.

table 3:

Based on the above research results, for patients with type 2 diabetes, the mattress lying on the bedding structure 100 of the present invention is more effective than the general mattress to enhance the microcirculation blood flow of the body surface, especially the coating. The mattress having the quilt structure 100 of the present invention has a microcirculation blood flow rise amount of more than 16% in the leg than that of the general mattress, and is statistically significant. In terms of warmth, the mattress with the bedding structure 100 of the present invention is also more effective in improving the body surface temperature than the general mattress.

In addition, the bedding structure 100 of the present invention has an effect of activating human skin cells in addition to the above-described effects of improving the blood flow rate and blood flow rate of the human body. The test for improving the skin texture of human body (3) will be disclosed below.

The test method used in the test (3) was as follows: during the test, the subject's front arm flexed side was drawn out of the range of 2 x 2 cm. Among them, the first zone (A) is "covering the fabric containing no far-infrared fibers", the second zone (B) is "covering the fabric with far-infrared fibers", and the third zone (C) is "not covering, not smearing" Any item." Also, the instrument will measure the parameters of the above skin and record it every seven days, and continue to count twice, for a total of fourteen days. In addition, the experiment was divided into a youth group (25 females, age 20±3 years old) and a middle-aged group (14 females, age 45±5 years old), and the statistical results of the trials of their youth group are recorded in Table 4. Table 5, and the statistical results of the middle-aged group are recorded in Tables 6 and 7.

In more detail, this test uses a roughness analyzer on the skin surface, which uses an ultraviolet probe to capture a sharp and contrasting skin texture, and then calculates the gap between the skin and the skin in the skin, and Explain the roughness of the skin with a mathematical formula. In this experiment, the greater the difference between the skin groove and the skin mound after the calculation of the computer software, the rougher the skin of the skin.

Table 4  <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td><b>Youth Group</b></td><td> Roughness Surface </ Td><td> Roughness Volume </td><td> Roughness R </td></tr><tr><td> Time/Group </td><td> A </td><td ><b>B</b></td><td> C </td><td> A </td><td><b>B</b></td><td> C </ Td><td> A </td><td><b>B</b></td><td> C </td></tr><tr><td> before test</td> <td> 543.87 </td><td><b>580.86</b></td><td> 597.41 </td><td> 58.68 </td><td><b>62.68</b> </td><td> 63.56 </td><td> 55.87 </td><td><b>61.25</b></td><td> 62.37 </td></tr><tr> <td> 7th</td><td> 568.5 </td><td><b>579.19</b></td><td> 602.04 </td><td> 61.43 </td><td ><b>64.62</b></td><td> 66.37 </td><td> 55.87 </td><td><b>62</b></td><td> 67.18 </ Td></tr><tr><td> 14th</td><td> 493.7 </td><td><b>450.45</b></td><td> 515.48 </td>< Td> 57.5 </td><td><b>55.31</b></td><td> 62.81 </td><td> 53.81 </td><td><b>53.31</b>< /td><td> 59.18 </td></tr><tr><td> Rate of Change % </td><td> -9.2 </td><td><b>-22.5</b>< /td><td> -13.7 </td><td> -2.0 </td><td><b>-11.8</b></td>< Td> -1.2 </td><td> -3.7 </td><td><b>-13.0</b></td><td> -5.1 </td></tr></TBODY> </TABLE> Note: Area A: Cloth 1 (thin, contrast cloth) Area B: Cloth 2 (thick, experimental cloth) Area C: blank control, no treatment was done Skin roughness change rate: [(after 14 days of use) Roughness - roughness before use) 粗糙度 roughness before use] × 100%  

table 5

Table 6  <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td><b>Middle-aged group</b></td><td> Roughness Surface < /td><td> Roughness Volume </td><td> Roughness R </td></tr><tr><td> Time/Group </td><td> A </td>< Td><b>B</b></td><td> C </td><td> A </td><td><b>B</b></td><td> C < /td><td> A </td><td><b>B</b></td><td> C </td></tr><tr><td> before the test </td ><td> 674.8 </td><td><b>684.2</b></td><td> 693.1 </td><td> 78.6 </td><td><b>77.6</b ></td><td> 81.2 </td><td> 77.8 </td><td><b>76.4</b></td><td> 80.7 </td></tr><tr ><td> 7 days</td><td> 668.5 </td><td><b>676.9</b></td><td> 688.3 </td><td> 76.5 </td>< Td><b>76.6</b></td><td> 84.3 </td><td> 75.5 </td><td><b>72.3</b></td><td> 77.5 < /td></tr><tr><td> 14th</td><td> 633.6 </td><td><b>558.4</b></td><td> 645.8 </td> <td> 71.5 </td><td><b>55</b></td><td> 78.6 </td><td> 73.1 </td><td><b>63.2</b> </td><td> 79.1 </td></tr><tr><td> rate of change </td><td> -6.1 </td><td><b>-18.4</b> </td><td> -6.8 </td><td> -9 </td><td><b>-29.1</b></td><td> -3.2 </td><td> -6 </td ><td><b>-17.3</b></td><td> -2 </td></tr></TBODY></TABLE> Note: Area A: Cloth 1 (thin, contrast cloth) Area B: Cloth 2 (thick, experimental cloth) Area C: blank control, no treatment was done. Skin roughness change rate: [(roughness after 14 days use - roughness before use) 粗糙度 roughness before use) 〕 × 100%  

Table 7

The results of this test are shown in Table 8. After 14 days of using the novel bedding structure 100, the subjects in the youth group were able to reduce skin roughness by 22.5% (surface), 11.8% (volume) and 13% ( R) In addition, the subjects in the middle-aged group were reduced by 18.4% (surface), 29.1% (volume), and 17.3% (R).

Table 8 - Roughness change rate  <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td> </td><td> Roughness surface (%) </td><td> Rough Degree volume (%) </td><td> roughness R (%) </td></tr><tr><td> young group</td><td> -22.5 % </td><td > -11.8 % </td><td> -13 % </td></tr><tr><td> middle age group</td><td> -18.4 % </td><td> -29.1 % </td><td> -17.3 % </td></tr></TBODY></TABLE>

The above test proves that after the long-term use of the quilt structure 100 of the present invention, the human skin can be divided into three layers of epidermis, dermis and subcutaneous tissue from the outside to the inside, and the far infrared rays radiated by the quilt structure 100 of the present invention are Will be completely absorbed in the epidermis, but will produce a warm effect in the subcutaneous tissue layer. Therefore, the energy of the wavelength portion emitted by the far-infrared rays emitted by the bedding structure 100 of the present invention can effectively absorb the tissue molecules and water molecules of the superficial skin, thereby achieving the effect of reducing the surface roughness of the skin.

The above embodiments are only used to exemplify the embodiments of the present invention, and to explain the technical features of the present invention, and are not intended to limit the scope of protection of the present invention. Any change or equalization that can be easily accomplished by those skilled in the art is within the scope of the present invention. The scope of the present invention should be determined by the scope of the patent application.

100‧‧‧Bedding structure

110‧‧‧Insulation

120‧‧‧First barrier

130‧‧‧second barrier

140‧‧‧First fabric layer

150‧‧‧Second cloth layer

160‧‧‧Metal materials

1 is a perspective view of a bedding structure of the present invention; FIG. 2 is a cross-sectional view of the bedding structure shown in FIG. 1; FIG. 3 is a cross-sectional view of another aspect of the bedding structure shown in FIG. 1; and FIG. A cross-sectional view of another embodiment of the present bedding structure.

Claims (8)

A bedding structure having a non-powered energy layer, comprising: a thermal insulation layer; a first barrier layer and a second barrier layer respectively disposed on opposite sides of the thermal insulation layer; a first fabric layer opposite to the thermal insulation layer The layer is disposed on one of the first barrier layer or the second barrier layer; and a second cloth layer is disposed on the other of the first barrier layer or the second barrier layer opposite to the insulation layer; Wherein, at least one of the insulating layer, the first cloth and the second cloth comprises a far-infrared fiber. The bedding structure having a non-powered energy layer according to claim 1, wherein the first fabric layer and the second fabric layer are a bristle cloth, a breathable cloth or a combination thereof. The bedding structure having a non-powered energy layer according to claim 1, wherein the first barrier layer and the second barrier layer are non-woven fabrics or fabrics containing a printing paint. A bedding structure having a non-powered energy layer as claimed in claim 1, wherein the insulating layer is wool, silk, fiber cotton, cotton, down, or a combination thereof. The bedding structure having a non-powered energy layer according to claim 1, wherein at least one of the first barrier layer or the second barrier layer has a textile of a metal material. The bedding structure having a non-powered energy layer according to claim 5, wherein the metal material is disposed in at least one of the first barrier layer or the second barrier layer in a manner of being shaped into metal fibers. The bedding structure having a non-powered energy layer according to claim 5, wherein the metal material is disposed on at least one of the first barrier layer or the second barrier layer in a coating manner. A bedding structure having a non-powered energy layer as claimed in claim 7, wherein the metal material is disposed on a side facing the insulating layer.