CN110991113A

CN110991113A - Design method of lightweight double-layer structure of palm mattress

Info

Publication number: CN110991113A
Application number: CN201911203190.6A
Authority: CN
Inventors: 黄龙; 廖廷茂; 黄照伟; 徐毅; 张丽影
Original assignee: Guizhou Daziran Technology Co Ltd
Current assignee: Guizhou Daziran Technology Co Ltd
Priority date: 2019-11-29
Filing date: 2019-11-29
Publication date: 2020-04-10
Anticipated expiration: 2039-11-29
Also published as: CN110991113B

Abstract

The invention discloses a design method of a lightweight double-layer structure of a palm mattress. The method comprises the steps of designing a palm mattress into an upper mattress layer and a lower mattress layer, establishing a palm mattress model, carrying out stress deformation analysis on the palm mattress model after applying human body load, measuring the deflection values of the upper mattress layer and the lower mattress layer in the palm mattress model, and setting the density of each mattress layer according to the deflection values of the upper mattress layer and the lower mattress layer to obtain the lightweight double-layer structure of the palm mattress. The method can guide the lightweight structural design of the palm mattress, design the palm mattress into an upper mattress layer structure and a lower mattress layer structure, and respectively design the densities of the upper mattress layer and the lower mattress layer, so that the lightweight of the mattress is realized. By the design of the invention, the total density of the palm mattress can be reduced, the material consumption of the mattress can be saved, the production cost can be reduced, and the quality of the product can be ensured.

Description

Design method of lightweight double-layer structure of palm mattress

Technical Field

The invention relates to the field of design of palm mattresses, in particular to a design method of a lightweight double-layer structure of a palm mattress.

Background

The palm mattress is made of palm fiber, coconut shell and the like, and belongs to plant fiber elastic materials. CN90100464.2 discloses a method for producing a plant fiber elastic material, which can be used for producing a palm mattress, wherein palm fibers (palm fibers) are curled and blown into a three-dimensional distribution by air flow, and then glue is sprayed to bond the palm fibers to obtain palm fiber elastic sheets, and then the palm fiber elastic sheets are stacked to obtain a layered palm fiber elastic material, and the palm fiber elastic material is bonded by adding latex, pressed into a sheet, hot-pressed, shaped, vulcanized and the like to obtain the palm mattress.

From the research situation of the mattress made of the plant fiber elastic material at home and abroad at present, most of researchers of the mattress are based on the comfort of the mattress and try to establish the incidence relation between the human body and the design of the mattress. The researches are basically based on functional requirements, few researches are carried out on the relationship between the mattress structure and the cost, the products are judged based on empirical values during development due to no scientific theoretical guidance, and the mattress structure is not optimally designed in many times.

In order to meet the durable use index of the mattress, the prior palm mattress is generally made by superposing palm sheet materials as much as possible, and the safe use coefficient is enlarged. This in fact results in an excess of material being used for the coir mattress, which increases the production costs of the coir mattress. Therefore, there is a need for a design method that optimizes the structure of a coir mattress.

Disclosure of Invention

The invention aims to provide a design method of a lightweight double-layer structure of a palm mattress. The method can guide the lightweight structural design of the palm mattress, design the palm mattress into an upper mattress layer structure and a lower mattress layer structure, and respectively design the densities of the upper mattress layer and the lower mattress layer, so that the lightweight of the mattress is realized. By the design of the invention, the total density of the palm mattress can be reduced, the material consumption of the mattress can be saved, the production cost can be reduced, and the quality of the product can be ensured.

The technical scheme of the invention is as follows: a design method of a lightweight double-layer structure of a palm mattress comprises the steps of designing the palm mattress into an upper mattress layer and a lower mattress layer, establishing a palm mattress model, carrying out stress deformation analysis on the palm mattress model after applying human body load, measuring the deflection values of the upper mattress layer and the lower mattress layer in the palm mattress model, and setting the density of each mattress layer according to the deflection values of the upper mattress layer and the lower mattress layer to obtain the lightweight double-layer structure of the palm mattress.

In the design method of the lightweight double-layer structure of the palm mattress, the method for establishing the palm mattress model and performing stress deformation analysis on the palm mattress model after applying the human body load is preferably to establish a material model and a mattress model by using ANSYS software and apply the human body load. Firstly establishing a material model of the mattress, then setting the size of the mattress by adopting a finite element solving method, establishing the mattress model by using the material model, applying human body load on the mattress model, and carrying out a stress deformation test on the mattress model after applying the human body load so as to obtain a corresponding deflection value; the mattress has the size of 2000mm in length, 1000mm in width and 120mm in thickness; the weight of the human body load is 80kg, and the area is 1700mm multiplied by 400 mm; the finite element method is a method for solving a numerical solution of a specific problem, firstly, a structural member of a structure is cut into a plurality of units, the behavior of each unit is described, then, the units are connected by nodes again, and a set of simultaneous algebraic equations is generated in the process.

In the design method of the lightweight double-layer structure of the palm mattress, the thickness of the lower mattress layer is 1-4 times that of the upper mattress layer.

In the design method of the lightweight double-layer structure of the palm mattress, the thickness of the lower mattress layer is 1-3 times of that of the upper mattress layer.

In the design method of the lightweight double-layer structure of the palm mattress, the thickness of the lower mattress layer is 1-2 times of that of the upper mattress layer.

In the method for designing a lightweight double-layer structure of a palm mattress, the deflection value is a circular measurement region having a radius of 12mm and having a stress center as a circle in a plane in which the stress center of the upper mattress layer or the lower mattress layer is located, and the deflection value obtained in the measurement region is the deflection value of the mattress layer.

In the method for designing the lightweight double-layered structure of the palm mattress, the density of each mattress layer is set according to the deflection values of the upper mattress layer and the lower mattress layer by setting the density of the lower mattress layer to be lower than the density of the upper mattress layer.

In the design method of the lightweight double-layer structure of the coir mattress, the method for setting the deflection values of the upper mattress layer and the lower mattress layer to the densities of the mattress layers comprises the following steps:

let the down deflection value of a mattress layer be 0.1x (mm), the density of the mattress layer be y (kg/m)³) The minimum density of the mattress layer is k (kg/m)³) K is 78-90;

when x < 1, y ═ k;

when x is more than or equal to 1 and less than 3, y is k +5 (x-1);

when x is equal to or greater than 3, y is k +20+10 (x-3).

In the design method of the lightweight double-layer structure of the palm mattress, k is 80-88.

In the design method of the lightweight double-layer structure of the palm mattress, k is 85.

The research process of the invention is as follows:

1. and performing super-elastic model research on the palm mattress by adopting ANSYS to derive the deformation distribution of the interlayer parts of the elastic supporting layer of the mattress. And establishing a palm material model, in particular a mountain palm material model. Specifically, the elastic modulus 46.7KPa and the Poisson ratio 0.2 of the palm mattress are input in ANSYS software, and a typical constitutive model combining the super-elastic material is established, wherein the strain energy function is described as follows:

and when N is 3, the special reduction form of the polynomial is a constitutive model in a Yeoh form, and curve fitting is performed on the constitutive model to obtain the mountain palm super-elastic material model.

2. Finite element solution is carried out, the mattress size is selected to be 200cm long, 100cm wide and 12cm thick, and due to the symmetry of the structure and the convenience of calculation, one half of the mattress can be taken for finite element analysis, so that 200m long and 50cm wide are required, and the model is shown in figure 1. In FIG. 1, the length is along the X-direction, the width is along the Z-direction, and the thickness is along the Y-direction.

Referring to the biological geometric data of the common general human body, the load application area is 1.7m multiplied by 0.4m, and the weight is 80kg (considering the safety operation, the human body mass is a larger value). Thus, the pressure applied to the model is: p ═ F ÷ S ═ 80 × 10 ÷ 1.7 × 0.4 ═ 1176.5 (pa). Due to the symmetry of the structure, the load application area is 1.7m multiplied by 0.2m, the uniform force application range is on the axis of the mattress, the structure and the load are symmetrical about the XY plane, and the load distribution is shown in figure 2.

3. And (5) carrying out interlaminar stress deformation analysis on the mattress model. Under the action of applying human body simulated load, the downwarping values of the mattress at the positions respectively 1cm, 3cm, 5cm, 7cm, 9cm and 11cm away from the upper surface of the mattress are analyzed, the distance from the measuring point of each layer to the stress center of the surface is 15cm, and fig. 3 is a downwarping value curved surface diagram of each node along the central line of different sections. As shown in fig. 3, the closer to the upper surface of the mattress, the less the compression deformation there. When the distance from the upper surface of the mattress is 1cm, the compression deformation with the distance more than 0.25m from the central line is positive, which shows that the part is pressed upwards, and the compression stress of the layer is more concentrated at the position of 0-0.25 m. From fig. 3, the layer 11cm from the upper surface is still under compressive stress at a distance of 0.3m from the centre line. The further away from the upper surface, the larger and larger the area that is deformed by the pressure. Since the total load of the human body on the object is constant under a certain condition, the larger the pressed area is, the more the compressive stress is dispersed.

4. Analyzing stress distribution of each layer of the mattress, and analyzing stress cloud charts of the mattress with the analysis distances of 1cm, 3cm, 5cm, 7cm, 9cm and 11cm from the upper surface of the mattress in a model for applying human body load to the mattress, wherein the stress charts of each layer are shown in figures 4-9. The application of stress is a locally distributed force applied to the upper surface of the mattress. The stress cloud is a cloud of horizontal sections at different thicknesses of the mattress, which is a top view. In the original drawing of the attached drawings, the bar-shaped cloud charts at the bottom of each drawing are gradually changed from left to right to show that the stress is increasingly greater. The closer to the force application surface shown in the original image, the closer the color of the force application area is to the color of the right part of the bar-shaped cloud picture, which shows that the stress is larger. Meanwhile, it can be clearly seen in fig. 4-9 that as the distance between the force-bearing surface and the force-applying surface increases, the stress area increases and the stress distribution tends to be uniform. From figures 4-9, there is a stress concentration in the upper left corner of the mattress, the effect of which is more pronounced closest to the bottom layer, primarily because the cross-section near the bottom is more affected by the bottom's fixation constraints, which are due to the fixation constraints.

5. The lightweight mattress model is established, and the analysis according to the analysis of the interlaminar stress deformation analysis and the analysis of the stress distribution of each layer of the mattress can be obtained, when the elastic supporting layer of the mattress is stressed by the weight of a human body, the stress borne by each layer is smaller along with the farther the layer surface is from the contact surface, and the stress tends to be uniformly distributed, namely the stress borne by the whole elastic supporting layer is a process that the gradient is gradually reduced, theoretically, the final stress distribution can be supposed to be uniformly distributed in the whole when the elastic supporting layer is thick enough, and the stress at the moment only needs to ensure the minimum stress required by the rigidity of the mattress. The plant fiber mattress manufactured under the same production process condition ensures the rigidity of the product mainly through the density of the mattress, and when the stress requirement is higher, the corresponding mattress density is required to be higher. Therefore, we can correlate the density of the mattress with the required stress, so as to build a structural model of the mattress, as shown in fig. 10. The density of the 1 st layer is the maximum, the density gradually decreases with the increase of the number of layers, and the density of the bottommost layer is the minimum. The density of the layer 1 should meet the rigidity requirement corresponding to the local maximum stress of the human body, and the bottommost layer must meet the integral supporting rigidity requirement of the human body, namely the average compressive stress requirement of the human body.

6. The stress conditions of elastic materials such as memory cotton, latex sponge, environment-friendly palm, sisal, coconut palm, spandex, palm substitute cotton, common sponge, bamboo charcoal cotton, blasting cotton and the like are the same as the stress conditions of the mountain palm materials analyzed by the method, so the method can be used for research. The mattresses made of various elastic materials can be layered according to the stress condition, and the supporting force provided by each layer of material meets the average pressure of a human body on the layer. Because the uniform elastic material has a certain range that the higher the density is, the higher the stress is, so that the mattress made of each elastic material can be provided with a light-weight layered structure. The research results of various elastic materials are similar to the research results of the invention, and finally, the functional relation between the downwarping value of the mattress layer of various materials and the layer density can be obtained, the functional formula can be similar to the formula of the method for setting the layer density by the deflection value of the mattress layer, and the difference lies in that the values of k, x and x are different along with the change rate of the deflection value.

The applicant has carried out a large number of experimental studies on the present invention, some of which are as follows:

according to the research process of the invention, the mattress can be theoretically divided into a plurality of layers to be arranged with density gradient, so that the lightweight structure of the mattress is realized, but according to the prior art, if the number of layers of the mattress is too large, the problems of complex process and low production efficiency are caused. The mattress with the lightweight structure is designed into a two-layer structure, so that the production process of the mattress with the lightweight structure is simplest and convenient to produce. In order to examine the lightweight double-layer structure model provided by the invention, the inventor manufactures a lightweight double-layer structure palm mattress and carries out experimental analysis on the lightweight double-layer structure palm mattress.

The same thickness specification of the prior plant fiber mattress is manufactured by adopting single density molding, and the density value of the mattress is formulated by referring to the durability index meeting the standard requirement of 'soft furniture palm fiber elastic mattress'. This experiment has made the palm mattress of mountain palm mattress two kinds of different density, forms the palm mattress of lightweight bilayer structure.

1. Experimental methods

(1) Two different density units are produced from the palm material respectively. The production method comprises the processes of adding latex into the palm fiber, pressing into a sheet, hot-pressing and shaping, vulcanizing and the like. According to the method of the invention, k value is set to be 85, a palm mattress with the total thickness of 120mm is manufactured and is designed to be 30mm thick at the upper mattress layer and 90mm thick at the lower mattress layer, and according to the relation between the deflection value and the density value of the invention, the density of the upper mattress layer is 120kg/m³(ii) a The density of the lower mattress layer is 90kg/m³。

(2) The two bed cushions are combined after hot pressing and vulcanization. The assembled mattress structure is shown in figure 11.

(3) Through tests, the overall density of the experimental double-layer mattress is 94-100kg/m³Compared with the whole lowest density (114 kg/m) of the prior common mattress³) The decrease is close to 15%.

2. Results and analysis of the experiments

(1) Mattress durability performance test

In order to effectively verify the durability performance of the mattress structure, the experiment is mainly carried out on samples of three batches with different comprehensive densities and with the specification of the mattress of 2000 × 1200 × 120mm according to the requirements of GB-T26706-2011 palm fiber elastic mattress standard for soft furniture. The test results are shown in table 1.

TABLE 1 comparative analysis table of durability test results

According to the index requirements of GB-T26706-2011 'Soft furniture palm fiber elastic mattress standard', the durability is equal to or larger than 90%, the mechanical index of the durability of the lightweight double-layer structure mattress is good, the quality requirement is met, and the durability is larger than 92% and reaches the level of the existing product.

(2) Mattress static compression performance test

In order to judge the static compression mechanical property index of the mattress more scientifically and accurately, the mechanical test of the lightweight double-layer structure mattress is carried out by adopting a detection method required by GB-T26706-2011 'Soft furniture palm fiber elastic mattress standard'. The test data are shown in table 2.

TABLE 2 GB-T26706-2011 static compression experimental data

According to the index requirements of GB-T26706-2011 'Soft furniture palm fiber elastic mattress standard', the product is qualified when the static compression is more than or equal to 88%. The lightweight double-layer structure mattress has the static compression index of about 93 percent, not only reaches the national standard and is a qualified product, but also reaches the level of the existing product.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, through analysis of the palm mattress, the distance between the stressed deformation area of the mattress and the force application surface is increased and increased after the mattress is applied with load. Because the total load of a human body lying on the mattress is constant, the stress is diffused to the periphery along with the stress center along with the downward transmission of the load, and the average stress borne by the lower part of the mattress is reduced. Therefore, the lower part of the mattress made of the palm fiber material does not need to keep higher supporting strength, and only needs to meet corresponding supporting force. However, since the conventional mattresses are produced at a uniform density, there is a case where the supporting force is excessive in the lower part of the mattress. The invention can carry out layered design on the palm mattress and reduce part of the density of the lower part of the mattress, thereby realizing the effects of reducing the total density of the mattress, saving the material consumption and the production cost.

2. According to the invention, the palm mattress is designed into a two-layer structure by utilizing the research result of the lightweight structure of the palm mattress, and the production process of the lightweight structure of the mattress is simplest and easy to realize. According to the limitation of the thickness relation of the upper mattress layer and the lower mattress layer, the thickness of the upper mattress layer is not too thin, and the upper mattress layer can be well supported by combining the thickness and the density of the upper mattress layer which are designed according to the limitation. And the thickness of the lower mattress layer is designed to be not less than that of the upper mattress layer, so that the upper mattress layer and the load can be well supported by the lower mattress layer, and the structure is reasonable.

3. Through the lightweight double-layer structure of the palm mattress designed by the invention, the mattress can still ensure the durability and the static compression index on the basis of reducing the total density of the palm mattress. The indexes not only meet the national standard, but also reach the level of the existing products.

4. The invention establishes the relation between the lower winding value of the palm mattress and the design density of the mattress, and the lightweight structure of the palm mattress meeting the standard can be conveniently and quickly designed by the method.

5. Through estimation, the total density of the lightweight palm mattress designed by the invention is reduced by about 15% compared with the total density of the existing palm mattress, and the total production cost can be reduced by about 12%. Because the palm mattress is a popular consumer product, the invention has good market prospect and can generate extremely high economic benefit.

In summary, the following steps: by the design of the invention, the total density of the palm mattress can be reduced, the material consumption of the mattress can be saved, and the production cost can be reduced; the lightweight structure of the mattress designed by the invention has simple production process and reasonable structure; the lightweight double-layer structure of the palm mattress designed by the invention has the advantages that on the basis of reducing the total density of the palm mattress, the quality not only meets the national standard, but also can reach the level of the existing product; when the lightweight double-layer structure of the palm mattress is designed, the palm mattress is convenient and quick; the invention reduces the total density of the prior palm mattress, has large degree of cost and large market potential.

Drawings

FIG. 1 is a finite element mesh partition of a mattress;

FIG. 2 is a load distribution of the mattress;

FIG. 3 is a graph of the sag values of various nodes along the centerline for different cross-sections;

FIG. 4 is a graph of Mises stress clouds at 1cm from the upper surface;

FIG. 5 is a graph of Mises stress clouds 3cm from the upper surface;

FIG. 6 is a graph of Mises stress clouds 5cm from the upper surface;

FIG. 7 is a graph of Mises stress clouds 7cm from the upper surface;

FIG. 8 is a graph of Mises stress clouds at 9cm from the upper surface;

FIG. 9 is a stress cloud of Mises 11cm from the upper surface;

FIG. 10 is a structural model of a lightweight mattress;

figure 11 is a schematic structural view of a double-layered palm mattress.

The labels in the figures are: 1-upper mattress layer, 2-lower mattress layer.

Detailed Description

The present invention is further illustrated by the following examples, which are not to be construed as limiting the invention. Processes not specifically mentioned for the present invention are all common in the art.

Example 1. A design method of a lightweight double-layer structure of a palm mattress comprises the following steps:

palm mattresses 2000mm long, 1800mm wide and 120mm thick were designed. The coir mattress is divided into an upper mattress layer and a lower mattress layer, the thickness of the lower mattress layer is designed to be 4 times of that of the upper mattress layer, namely the thickness of the upper mattress layer is 24mm, and the thickness of the upper mattress layer is 96 mm.

Firstly, using ANSYS software to establish a palm material model of the mattress. A finite element solving method is adopted, and a palm mattress model corresponding to the length, the width and the thickness is built by using a palm material model. Then applying human body load on the palm mattress model, wherein the load area is 1700mm multiplied by 800mm, and the weight is 80 kg; and (3) carrying out a stress deformation test on the mattress model subjected to human body load to obtain the downwarping values of the upper mattress layer and the lower mattress layer, selecting a selection point of the downwarping value on a plane where a stress center of the mattress layer is located, and selecting a deflection value within 12mm from the stress center of the mattress layer as the downwarping value.

Finally, setting the density of the mattress layer according to the deflection values of the upper mattress layer and the lower mattress layer, wherein the deflection value of one mattress layer is 0.1x (mm), and the density of the mattress layer is y (kg/m)³) The minimum density of the mattress layer is k (kg/m)³) K is 78; when x is less than 1, y is 78; when x is more than or equal to 1 and less than 3, y is 78+5 (x-1); when x is larger than or equal to 3, y is 98+10 (x-3), and the calculation is as follows: the density of the upper mattress layer is 117kg/m³The density of the lower mattress layer is 88kg/m³。

That is, the palm fiber mattress with the length of 2000mm, the width of 1800mm and the thickness of 120mm is designed into a light double-mattress layer structure by the invention. Wherein the upper mattress layer has a thickness of 24mm and a density of 117kg/m³(ii) a The lower mattress layer has a thickness of 96mm and a density of 88kg/m³。

Example 2. A design method of a lightweight double-layer structure of a palm mattress is disclosed, and a model establishing method and a stress deformation testing method of the embodiment are the same as those of embodiment 1. This implementationExample a coir mattress with a length of 1800mm, a width of 1600mm and a thickness of 120mm is designed as a light-weight double mattress structure. The thickness of the lower bed cushion layer is designed to be 3.5 times of the thickness of the upper bed cushion layer, the thickness of the upper bed cushion layer is 26.7mm, the thickness of the lower bed cushion layer is 93.3mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the mattress layer is located, and a deflection value within 10mm away from the stress center of the mattress layer is selected as the lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, wherein the k value is 80, and the designed density of the upper mattress layer is calculated to be 118kg/m³The design density of the lower mattress layer is 91kg/m³。

That is, the palm fiber mattress with the length of 2000mm, the width of 1800mm and the thickness of 120mm is designed into a light double-mattress layer structure by the invention. Wherein the upper mattress layer has a thickness of 26.7mm and a density of 118kg/m³(ii) a The lower mattress layer has a thickness of 93.3mm and a density of 91kg/m³。

Example 3. A design method of a lightweight double-layer structure of a palm mattress is disclosed, and a model establishing method and a stress deformation testing method of the embodiment are the same as those of embodiment 1. The embodiment designs a coir mattress with the length of 1800mm, the width of 1600mm and the thickness of 150mm into a light-weight double-mattress layer structure. The thickness of the lower bed cushion layer is designed to be 3 times of that of the upper bed cushion layer, the thickness of the upper bed cushion layer is 37.5mm, the thickness of the lower bed cushion layer is 112.5mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the mattress layer is located, and a deflection value within 6mm away from the stress center of the mattress layer is selected as a lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, wherein the k value is 85, and the designed density of the upper mattress layer is calculated to be 122kg/m³The design density of the lower bed cushion layer is 94kg/m³。

Namely, the palm mattress with the length of 2000mm, the width of 1800mm and the thickness of 150mm is designed into a light-weight double-mattress layer structure by the invention. Wherein the upper mattress layer has a thickness of 37.5mm and a density of 122kg/m³(ii) a The lower bed cushion layer has a thickness of 112.5mm and a density of 94kg/m³。

Example 4. A design method of a lightweight double-layer structure of a palm mattressThe model building method and the stress deformation test method were the same as in example 1. The embodiment designs the coir mattress with the length of 1800mm, the width of 180mm and the thickness of 180mm into a light-weight double-mattress layer structure. The thickness of the lower bed cushion layer is designed to be 2.5 times of that of the upper bed cushion layer, the thickness of the upper bed cushion layer is 51.4mm, the thickness of the lower bed cushion layer is 128.6mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the mattress layer is located, and a deflection value within 3mm away from the stress center of the mattress layer is selected as a lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, wherein the k value is 88, and the designed density of the upper mattress layer is calculated to be 120kg/m³The design density of the lower bed cushion layer is 96kg/m³。

The palm mattress with the length of 2000mm, the width of 1800mm and the thickness of 180mm is designed into a light-weight double-mattress layer structure through the invention. Wherein the upper mattress layer has a thickness of 51.4mm and a density of 120kg/m³(ii) a The lower bed cushion layer has a thickness of 128.6mm and a density of 96kg/m³。

Example 5. A design method of a lightweight double-layer structure of a palm mattress is disclosed, and a model establishing method and a stress deformation testing method of the embodiment are the same as those of embodiment 1. Wherein the applied area of the human body load is 1800mm multiplied by 800mm, and the weight is 90 kg. The embodiment designs the coir mattress with the length of 1800mm, the width of 180mm and the thickness of 180mm into a light-weight double-mattress layer structure. The thickness of the lower bed cushion layer is designed to be 2 times of the thickness of the upper bed cushion layer, the thickness of the upper bed cushion layer is 60mm, the thickness of the lower bed cushion layer is 120mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the mattress layer is located, and a deflection value within 4mm from the stress center of the bed cushion layer is selected as a lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, wherein the k value is 90, and the designed density of the upper mattress layer is calculated to be 119kg/m³The design density of the lower bed cushion layer is 96kg/m³。

The palm mattress with the length of 2000mm, the width of 1800mm and the thickness of 180mm is designed into a light-weight double-mattress layer structure through the invention. Wherein the upper mattress layer has a thickness of 60mm and a density of 119kg/m³(ii) a The lower mattress layer has a thickness of 120mm and a density of 96kgm³。

Example 6. A design method of a lightweight double-layer structure of a palm mattress is disclosed, and a model establishing method and a stress deformation testing method of the embodiment are the same as those of embodiment 1. Wherein the applied area of the human body load is 1800mm multiplied by 750mm, and the weight is 90 kg. The embodiment designs the palm mattress with the length of 1800mm, the width of 180mm and the thickness of 300mm into a light-weight double-mattress layer structure. The thickness of the lower bed cushion layer is designed to be 1 time of that of the upper bed cushion layer, the thicknesses of the upper bed cushion layer and the lower bed cushion layer are both 150mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the bed cushion layer is located, and a deflection value within 4mm from the stress center of the bed cushion layer is selected as a lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, wherein the k value is 88, and the designed density of the upper mattress layer is calculated to be 117kg/m³The design density of the lower bed cushion layer is 97kg/m³。

Namely, the palm mattress with the length of 2000mm, the width of 1800mm and the thickness of 300mm is designed into a light-weight double-mattress layer structure by the invention. Wherein the upper mattress layer has a thickness of 150mm and a density of 117kg/m³(ii) a The lower bed cushion layer has a thickness of 150mm and a density of 97kg/m³。

Example 7. A design method of a lightweight double-layer structure of a palm mattress is disclosed, and a model establishing method and a stress deformation testing method of the embodiment are the same as those of embodiment 1. Wherein the applied area of the human body load is 1850mm multiplied by 800mm, and the weight is 85 kg. The embodiment designs the coir mattress with the length of 1800mm, the width of 180mm and the thickness of 180mm into a light-weight double-mattress layer structure. The thickness of the lower bed cushion layer is designed to be 1.5 times of that of the upper bed cushion layer, the thickness of the upper bed cushion layer is 72mm, the thickness of the lower bed cushion layer is 108mm, the lower winding value of the upper bed cushion layer and the lower bed cushion layer is selected on the plane where the stress center of the mattress layer is located, and a deflection value within 6mm away from the stress center of the mattress layer is selected as a lower deflection value. Setting the density of the mattress layer by using the deflection values of the upper mattress layer and the lower mattress layer, and calculating the design density of the upper mattress layer to be 115kg/m by taking the k value to be 84³The design density of the lower bed cushion layer is 95kg/m³。

Namely, the length is 2000mm and the width is 2000mmThe 1800mm and 180mm thick coir mattress design is light-weight double mattress layer structure. Wherein the upper mattress layer has a thickness of 72mm and a density of 115kg/m³(ii) a The lower bed cushion layer has a thickness of 108mm and a density of 95kg/m³。

Claims

1. A design method of a lightweight double-layer structure of a palm mattress is characterized in that: designing a coir mattress into an upper mattress layer and a lower mattress layer, establishing a coir mattress model, carrying out stress deformation analysis on the coir mattress model after applying human body load, measuring the deflection values of the upper mattress layer and the lower mattress layer in the coir mattress model, and setting the density of each mattress layer according to the deflection values of the upper mattress layer and the lower mattress layer to obtain the lightweight double-layer structure of the coir mattress.

2. The design method of the lightweight double-layer structure of the palm mattress according to claim 1, characterized in that: the thickness of the lower mattress layer is 1-4 times of the thickness of the upper mattress layer.

3. The design method of the lightweight double-layer structure of the palm mattress according to claim 2, characterized in that: the thickness of the lower mattress layer is 1-3 times of the thickness of the upper mattress layer.

4. The design method of the lightweight double-layer structure of the palm mattress according to claim 3, characterized in that: the thickness of the lower mattress layer is 1-2 times of the thickness of the upper mattress layer.

5. The design method of the lightweight double-layer structure of the palm mattress according to claim 1, characterized in that: the deflection value is a circular measuring area with the stress center as a circle and the set radius of 12mm in the plane of the stress center of the upper mattress layer or the lower mattress layer, and the deflection value obtained in the measuring area is the deflection value of the mattress layer.

6. The design method of the lightweight double-layer structure of the palm mattress according to claim 1, characterized in that: the method for setting the density of each mattress layer according to the deflection values of the upper mattress layer and the lower mattress layer is to reduce the density of the lower mattress layer relative to the density of the upper mattress layer.

7. The design method of the lightweight double-layer structure of the palm mattress according to claim 1, characterized in that: the method for setting the density of each mattress layer by the deflection values of the upper mattress layer and the lower mattress layer comprises the following steps:

when x < 1, y ═ k;

when x is more than or equal to 1 and less than 3, y is k +5 (x-1);

when x is equal to or greater than 3, y is k +20+10 (x-3).

8. The design method of the lightweight double-layer structure of the palm mattress according to claim 7, characterized in that: and k is 80-88.

9. The design method of the lightweight double-layer structure of the palm mattress according to claim 8, characterized in that: k is 85.