A construction method of a bionic ecological wild flower arrangement
By collecting and processing wild plants, and combining biomimetic units and center of gravity calculation, we have constructed an eco-friendly wild flower arrangement, which solves the problem of the solidification of traditional flower arrangement, realizes dynamic aesthetic expression and improves stability, extends the viewing period, and broadens the application scenarios.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- 章蓓蓓
- Filing Date
- 2026-04-13
- Publication Date
- 2026-06-12
Smart Images

Figure CN122181777A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of floral art creation technology, specifically a method for constructing an eco-friendly, wild floral arrangement. Background Technology
[0002] Currently, traditional flower arranging (Japanese, Korean, and traditional Chinese vase arrangements, etc.) often has fixed styling paradigms and technical requirements. For example, Japanese flower arranging uses symmetrical composition, while Korean flower arranging uses a cluster of flowers. In the creative process, it is easy to fall into the rigid dilemma of "a thousand flowers looking the same," making it difficult to achieve a figurative, dynamic, and eco-friendly expression of natural forms, animal movements, and human dance postures. It is also impossible to integrate the original dynamic beauty of the wild and natural into flower arranging creation, which limits the artistic expression and scene adaptability of flower arranging works. Therefore, we propose a method for constructing eco-friendly wild and natural flower arranging to solve the above-mentioned problems. Summary of the Invention
[0003] To address the shortcomings of existing technologies, this invention provides a method for constructing an eco-friendly, wildflower arrangement. This method solves the problems of traditional flower arrangements, such as rigid design paradigms, a tendency to produce monotonous designs, difficulty in concretely expressing the original dynamic beauty of the wild, poor stability due to a lack of scientific mechanical design, rough handling of floral materials leading to easy wilting, short viewing period, and limited scene adaptability and artistic expression.
[0004] To achieve the above objectives, the present invention provides the following technical solution: a method for constructing an eco-friendly, wildflower arrangement, comprising the following steps:
[0005] S1. Collect living plant materials from the mountain environment. The plant materials include at least load-bearing main branches, flexible auxiliary branches, and moss or vines. Immediately after collection, make oblique cuts on the cut surfaces and spray with a moisturizing agent.
[0006] S2. Perform structural mechanics testing on the plant material treated in S1 to obtain its Janka hardness value; based on the hardness value, match bionic units with similar mechanical support requirements from a preset bionic morphological structure library, wherein the bionic units include animal limb postures or natural landscape skeletons.
[0007] S3. Based on the distribution of mechanical support points of the bionic unit, the insertion point and tilt angle of the load-bearing main branch, as well as the winding path and density ratio of the flexible auxiliary branches, are determined by the center of gravity calculation to generate spatial layout parameters; wherein, the goal of the center of gravity calculation is to make the projection of the overall center of gravity of the assembly on the horizontal plane fall into the support surface of the flower pot or natural fixed object, and the shortest distance from the edge of the support surface is not less than 2cm.
[0008] S4. Insert the load-bearing main branch into the flower container filled with a fixed medium at the aforementioned angle, ensuring that the depth of the main branch's bottom end inserted into the medium satisfies the following: based on the Janka hardness value of the main branch and the maximum bending moment of the biomimetic shape, the static friction generated at this depth is sufficient to resist the slippage of the main branch; subsequently, tie or insert flexible auxiliary branches, moss, and vines onto the predetermined nodes of the main branch according to the aforementioned winding path to form a biomimetic shape;
[0009] S5. Spray a plant-based shaping agent containing plant essential oils onto the biomimetic shape formed in S4. After the shaping agent has cured, the construction is complete.
[0010] This invention provides a simulated natural wildflower arrangement, constructed using the method described above, comprising:
[0011] The flower vase is filled with a granular fixing medium.
[0012] At least one load-bearing main branch has its bottom end inserted into the fixing medium and fixed by static friction with the medium particles;
[0013] At least one flexible auxiliary branch, which is wrapped around and fixed to the load-bearing main branch to form a biomimetic shape; and moss or vines attached to the main branch and auxiliary branch.
[0014] Beneficial effects
[0015] This invention provides a method for constructing an eco-friendly, wildflower arrangement. Compared with existing technologies, it has the following advantages:
[0016] This method of constructing biomimetic wildflower arrangements breaks away from the fixed paradigm of traditional flower arrangement. Through precise matching of biomimetic units, it achieves a dynamic and biomimetic expression of natural scenery and animal postures, restores the original dynamic beauty of the wild, solves the problem of "all flowers looking the same", and greatly enhances the artistic creativity and visual expressiveness of the works.
[0017] By incorporating structural mechanics and center of gravity calculations into the design, and scientifically selecting main and auxiliary branches and determining fixed parameters, the stability of the shape structure is fundamentally ensured, avoiding problems such as tipping over and slippage of floral materials, thus improving the overall durability of the work. The spatial layout and density ratio are precisely controlled to create a harmonious and natural mountain visual effect. Combined with moisturizing and shaping agents made of natural plant essential oils, it releases natural fragrances, bringing an immersive mountain healing experience, soothing emotions and relieving physical and mental fatigue.
[0018] Through standardized scientific processing and the application of environmentally friendly media and fixatives, the freshness of the flowers and the viewing period of the artwork are extended, and the materials contain no harmful components, taking into account both plant protection and environmental friendliness; the standardized construction process can be adapted to multiple scenarios such as homes, gardens, health and wellness spaces, and art exhibitions, meeting diverse application needs and broadening the application boundaries of floral art. Attached Figure Description
[0019] Figure 1 This is a flowchart of a method for constructing an eco-friendly wildflower arrangement according to the present invention. Detailed Implementation
[0020] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0021] like Figure 1 As shown:
[0022] A method for constructing an eco-friendly, wildflower arrangement includes the following steps:
[0023] S1. Collect live plant material from the wild environment. The plant material should include at least load-bearing main branches, flexible auxiliary branches, and moss or vines. During collection, ensure the integrity of the plant material and minimize damage to branches, leaves, and moss / vines. Within one hour of collection, make a slanted cut at an angle of 45°-60° to increase the water absorption area of the cut surface. Simultaneously, spray the cut surface and the entire plant material with a moisturizing agent to prevent wilting due to moisture loss and maintain its freshness. The moisturizing agent is a specialized water-locking and moisturizing spray containing plant essential oils, with the essential oil percentage being 0.1%-0.5% by weight.
[0024] S2. Structural mechanics testing is performed on the plant materials treated in S1. The Janka hardness value is obtained using professional mechanical testing equipment. The load-bearing main branches are selected from woody branches with a Janka hardness ≥500N to ensure sufficient mechanical support, serving as the framework for the floral arrangement. Flexible auxiliary branches are selected from branches with a Janka hardness ≤200N and a diameter ratio of 1:3 to 1:5 to the main branch diameter to ensure flexibility, facilitating winding and creating a reasonable thickness match with the main branches, enhancing the overall harmony of the arrangement. Based on the measured Janka hardness values, biomimetic units with similar mechanical support requirements are matched from a pre-set biomimetic structure library. These biomimetic units include animal limb postures, such as a crane spreading its wings, a deer crouching, a bird soaring through the air, and a human dancing; or natural landscape frameworks, such as layered mountains, winding streams, and leaning pines. The biomimetic structure library pre-stores the mechanical support parameters, shape characteristics, and suitable plant material hardness ranges for various biomimetic units.
[0025] S3. Based on the distribution of mechanical support points of the matched bionic units, the center of gravity is simulated and calculated using center of gravity calculation software to determine the insertion point and tilt angle of the load-bearing main branches, as well as the winding path and density ratio of the flexible auxiliary branches, generating precise spatial layout parameters. The core objective of the center of gravity calculation is to ensure that the projection of the overall center of gravity of the floral arrangement onto the horizontal plane falls within the support surface of the vase or natural fixture, with a minimum distance of 2cm from the edge of the support surface, ensuring the overall stability of the floral arrangement and preventing tipping. The density ratio is the ratio of the surface area of the visible part of the main branches to the surface area of the auxiliary branches and the covered parts of the flowers; this ratio is strictly controlled between 3:1 and 2:1.
[0026] S4. Prepare the flower container and fill it with a fixing medium, which is a mixture of perlite, vermiculite, and water in a volume ratio of 2:1:3. Insert the main supporting branch into the fixing medium at the angle determined in S3. The insertion depth of the bottom of the main branch into the medium is determined based on the Janka hardness value of the main branch and the maximum bending moment of the biomimetic shape, ensuring that the static friction generated at this insertion depth is sufficient to resist the slippage of the main branch. Subsequently, according to the winding path determined in S3, tie or insert flexible auxiliary branches, moss, and vines to the predetermined nodes of the main branch using biodegradable hemp rope or plant fibers to form a biomimetic shape. The tying force should be strictly controlled between 0.5-1.0N to avoid damaging the plant material due to excessive tightness.
[0027] S5. Evenly spray the biomimetic shape constructed in S4 with a plant-based setting agent. After the setting agent has naturally cured, the overall construction of the simulated wildflower arrangement is complete. The setting agent contains plant essential oils (0.2%-0.6% by mass), and its components include, by mass percentage: chitosan 0.3%-0.8%, sucrose 1.5%-2.5%, citric acid 0.05%-0.15%, with the balance being water; the amount of setting agent sprayed is 3-5 ml per 100 grams of plant material.
[0028] The plant essential oil is selected from at least one of lavender essential oil, tea tree essential oil, jasmine essential oil, rose essential oil, lemon essential oil, rosemary essential oil, or eucalyptus essential oil.
[0029] This invention provides a simulated wild mountain flower arrangement, constructed using the above-described method, comprising:
[0030] The flower container is filled with the aforementioned granular fixing medium.
[0031] At least one load-bearing main branch has its bottom end inserted into a fixed medium and fixed by static friction with the medium particles, providing mechanical support for the overall shape;
[0032] At least one flexible auxiliary branch is wrapped around and fixed to the load-bearing main branch, forming a pre-designed biomimetic shape in conjunction with the main branch;
[0033] Moss or vines attach to the main and secondary branches, enriching the shape and creating a natural, wild visual effect.
[0034] Example:
[0035] Wildflower arrangement featuring an eco-friendly crane spreading its wings;
[0036] S1. Collect pine branches with a hardness of about 600N from the wild as load-bearing main branches, and willow branches with a hardness of about 180N and a diameter of 1 / 4 of the main branches as flexible auxiliary branches. At the same time, collect fresh moss and ivy vines. Within 30 minutes after collection, make a 50° oblique cut on all branches and spray with a moisturizer containing 0.3% lavender essential oil. Spray the moss and vines with a mist to keep them moist.
[0037] S2. According to mechanical testing, the hardness of the pine main branch is 620N and the hardness of the willow auxiliary branch is 175N, which meets the requirements of the hardness and diameter ratio of the main and auxiliary branches. The "crane spreading its wings" biomimetic unit is matched from the biomimetic morphology structure library. This unit requires the main branch to have strong support and the auxiliary branch to have good flexibility, which is highly compatible with the mechanical characteristics of the collected flower materials.
[0038] S3. Based on the distribution of mechanical support points of a crane spreading its wings, the insertion point of the pine main branch is determined to be 3cm to the left of the center of the flower container, with an inclination angle of 30°, through center of gravity calculation. The winding path of the willow auxiliary branches extends upward in an arc from the middle and lower part of the main branch, simulating the shape of a crane's wings spreading, with a density ratio controlled at 2.5:1 (visible surface area of the main branch: surface area covered by the auxiliary branches). According to calculation, the overall center of gravity projection of the assembly falls within the support surface of the flower container, and the shortest distance between it and the edge of the support surface is 3cm.
[0039] S4. Select a ceramic flowerpot and fill it with a mixture of perlite, vermiculite and water in a volume ratio of 2:1:3 as a fixing medium. Insert the main pine branch into the medium at a 30° angle. The insertion depth is determined to be 15cm based on bending moment calculation. The static friction generated at this depth can effectively resist the slippage of the main branch. Use biodegradable hemp rope and tie the willow auxiliary branches to the main branch along the preset arc path with a binding force of 0.8N. At the same time, lay moss on the middle and lower part of the main branch and let ivy vines twine around the ends of the auxiliary branches to form a biomimetic shape of a crane spreading its wings.
[0040] S5. Prepare the plant setting agent, by weight percentage: chitosan 0.5%, sucrose 2.0%, citric acid 0.1%, lemon essential oil 0.4%, and the remainder is water; spray 4ml of the setting agent evenly over the entire biomimetic shape for every 100g of plant material, place it in a cool and ventilated place, and wait for the setting agent to cure naturally to complete the construction of the biomimetic crane spreading its wings shape wild flower arrangement.
[0041] This scheme breaks away from the fixed paradigm of traditional flower arrangement. Through the precise matching of biomimetic units, it achieves a dynamic and eco-friendly expression of natural scenery and animal postures, restores the original dynamic beauty of the mountains and fields, solves the problem of "all flowers looking the same", and greatly enhances the artistic creativity and visual expression of the works.
[0042] By incorporating structural mechanics and center of gravity calculations into the design, and scientifically selecting main and auxiliary branches and determining fixed parameters, the stability of the shape structure is fundamentally ensured, avoiding problems such as tipping over and slippage of floral materials, thus improving the overall durability of the work. The spatial layout and density ratio are precisely controlled to create a harmonious and natural mountain visual effect. Combined with moisturizing and shaping agents made of natural plant essential oils, it releases natural fragrances, bringing an immersive mountain healing experience, soothing emotions and relieving physical and mental fatigue.
[0043] Through standardized scientific processing and the application of environmentally friendly media and fixatives, the freshness of the flowers and the viewing period of the artwork are extended, and the materials contain no harmful components, taking into account both plant protection and environmental friendliness; the standardized construction process can be adapted to multiple scenarios such as homes, gardens, health and wellness spaces, and art exhibitions, meeting diverse application needs and broadening the application boundaries of floral art.
[0044] Finally, it should be noted that the above descriptions are merely preferred embodiments of the present invention and are not intended to limit the present invention. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A method for constructing an eco-friendly, wildflower arrangement, characterized by: Includes the following steps: S1. Collect living plant materials from the mountain environment. The plant materials include at least load-bearing main branches, flexible auxiliary branches, and moss or vines. Immediately after collection, make oblique cuts on the cut surfaces and spray with a moisturizing agent. S2. Perform structural mechanics testing on the plant material treated in S1 to obtain its Janka hardness value; based on the hardness value, match bionic units with similar mechanical support requirements from a preset bionic morphological structure library, wherein the bionic units include animal limb postures or natural landscape skeletons. S3. Based on the distribution of mechanical support points of the bionic unit, the insertion point and tilt angle of the load-bearing main branch, as well as the winding path and density ratio of the flexible auxiliary branches, are determined by the center of gravity calculation to generate spatial layout parameters; wherein, the goal of the center of gravity calculation is to make the projection of the overall center of gravity of the assembly on the horizontal plane fall into the support surface of the flower pot or natural fixed object, and the shortest distance from the edge of the support surface is not less than 2cm. S4. Insert the load-bearing main branch into the flower container filled with a fixed medium at the aforementioned angle, ensuring that the depth of the main branch's bottom end inserted into the medium satisfies the following: based on the Janka hardness value of the main branch and the maximum bending moment of the biomimetic shape, the static friction generated at this depth is sufficient to resist the slippage of the main branch; subsequently, tie or insert flexible auxiliary branches, moss, and vines onto the predetermined nodes of the main branch according to the aforementioned winding path to form a biomimetic shape; S5. Spray a plant-based shaping agent containing plant essential oils onto the biomimetic shape formed in S4. After the shaping agent has cured, the construction is complete.
2. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S2, the load-bearing main branches are selected from woody branches with a hardness of ≥500N (Jianka); the flexible auxiliary branches are selected from branches with a hardness of ≤200N (Jianka) and a diameter ratio of 1:3 to 1:5 to the main branch diameter.
3. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S3, the density ratio is the ratio of the surface area of the visible part of the main branch to the surface area of the auxiliary branches and the part covered by flowers and grasses, and this ratio is controlled between 3:1 and 2:
1.
4. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S4, the fixing medium is a mixture of perlite, vermiculite and water in a volume ratio of 2:1:
3.
5. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S4, the binding is done with biodegradable hemp rope or plant fiber, and the binding force is controlled between 0.5-1.0N.
6. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S5, the components of the shaping agent by mass percentage include: chitosan 0.3%-0.8%, sucrose 1.5%-2.5%, citric acid 0.05%-0.15%, and the balance being water; the spraying amount is calculated as 3-5 ml per 100 grams of plant material.
7. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: In S1, oblique cutting and moisturizing treatment are completed within 1 hour after collection.
8. The method for constructing a simulated natural wildflower arrangement according to claim 1, characterized in that: The humectant containing plant essential oils contains 0.1%-0.5% by mass of plant essential oils; the setting agent containing plant essential oils contains 0.2%-0.6% by mass of plant essential oils.
9. The method for constructing an eco-friendly, wildflower arrangement according to claim 1, characterized in that: The plant essential oil is selected from at least one of lavender essential oil, tea tree essential oil, jasmine essential oil, rose essential oil, lemon essential oil, rosemary essential oil, or eucalyptus essential oil.
10. A kind of simulated natural wildflower arrangement, characterized in that, Constructed using the method described in any one of claims 1 to 9, comprising: The flower vase is filled with a granular fixing medium. At least one load-bearing main branch has its bottom end inserted into the fixing medium and fixed by static friction with the medium particles; At least one flexible auxiliary branch, which is wrapped around and fixed to the load-bearing main branch to form a biomimetic shape; and moss or vines attached to the main branch and auxiliary branch.