An extended, deformation-resistant rubberwood board
By introducing stress-dispersing and reinforcing components into rubberwood boards, the problem of localized deformation caused by stress concentration is solved, resulting in better structural stability and extended service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LINYI FENGCUI WOOD IND CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-06-30
Smart Images

Figure CN224425855U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of rubberwood board technology, and in particular to an extended and deformation-resistant rubberwood board. Background Technology
[0002] Rubberwood boards are made from rubberwood using advanced woodworking techniques and processes. They are uniform in texture, easy to process, and have a variety of uses. In furniture manufacturing, rubberwood boards can be used to make tables, chairs, cabinets, etc. Their high hardness and wear resistance also make them suitable for flooring. Furthermore, rubberwood boards have a natural grain and warm color, making them suitable for interior decoration, such as wainscoting and baseboards. In the construction industry, cross-laminated rubberwood (CLT) can be used for wall panels, floor slabs, and roof panels, offering advantages such as lightweight, high strength, earthquake resistance, and fire resistance. Rubberwood can also be used to make handicrafts, toys, pallets, and wooden boxes.
[0003] A search revealed that the document with publication number "CN219953851U" mentions "This utility model discloses a wear-resistant rubberwood board, relating to the field of rubberwood board technology, including a rubber board structure. A protective frame is fixedly connected to one side of the rubber board structure. A locking block is fixedly connected to the outer wall of the rubber board structure. The locking block engages with a slotted plate. A connecting locking plate is fixedly connected to the outer wall of the slotted plate. The connecting locking plate engages with a locking groove. A first mounting hole is provided on the connecting locking plate, and a second mounting hole is provided on the locking groove. A mounting screw is threaded into the second mounting hole. This utility model achieves the effect of simplifying the device by connecting the locking block and the slotted plate..." The interlocking mechanism between the interlocking blocks and the slot plate allows for quick and stable installation, resulting in enhanced wear resistance. The addition of a fiberglass layer to the rubber plate structure further strengthens the device's pressure resistance, extending its lifespan and meeting user needs.
[0004] However, when existing rubberwood boards are subjected to external forces, stress tends to concentrate in localized areas, leading to localized deformation. This makes these areas prone to bending, twisting, or cracking, affecting the overall performance and service life of the boards. In addition, existing rubberwood boards have a simple structure, consisting of only simple wood. When subjected to long-term external pressure, they are prone to twisting, bending, and other deformations, failing to maintain good planar stability and affecting their flatness and structural integrity during use.
[0005] Therefore, we provide an extended, deformation-resistant rubberwood board to solve the above problems. Utility Model Content
[0006] To overcome the above deficiencies, this utility model provides an extended, deformation-resistant rubberwood board, aiming to solve the aforementioned problems.
[0007] To achieve the above objectives, this utility model provides the following technical solution:
[0008] An extended, deformation-resistant rubberwood board includes a board body, a first connector on the left side of the board body, a second connector on the right side of the board body, a wear-resistant layer on the upper surface of the board body, a top waterproof layer on the inner side of the wear-resistant layer, a stress-dispersing component below the top waterproof layer, the stress-dispersing component including a stress-dispersing layer installed below the top waterproof layer, stress-dispersing strips installed on the surface of the stress-dispersing layer, a reinforcing component installed on the inner side of the board body, the reinforcing component including a first reinforcing layer installed on the inner side of the board body, and a first reinforcing mesh on the lower inner side of the board body.
[0009] As a further description of the above technical solution:
[0010] The plate body and the first connector are fixedly connected. The wear-resistant layer is made of melamine-impregnated paper, and the top waterproof layer is made of polyurethane waterproof paint.
[0011] As a further description of the above technical solution:
[0012] The stress-dispersing layer is fixedly connected to the top waterproof layer by high-temperature resistant adhesive. The stress-dispersing strip is wavy and made of titanium-nickel alloy, and there are eight sets of the stress-dispersing strip.
[0013] As a further description of the above technical solution:
[0014] A reinforcing rib is provided below the stress dispersion layer, a fixing bolt is installed on the inner side of the reinforcing rib, and a buffer pad is provided below the reinforcing rib. The reinforcing rib is fixedly connected to the buffer pad by the fixing bolt.
[0015] As a further description of the above technical solution:
[0016] A rubberwood base layer is provided below the first reinforcing mesh, the first reinforcement layer is made of high-density fiberboard, and the first reinforcing mesh is composed of FRP strips.
[0017] As a further description of the above technical solution:
[0018] A second reinforcing mesh is provided below the rubberwood base layer, and a second reinforcement layer is provided below the second reinforcing mesh. The second reinforcing mesh is fixedly connected to the second reinforcement layer by a resin adhesive.
[0019] As a further description of the above technical solution:
[0020] Below the second reinforcement layer is a bottom waterproof layer, which is made of polyvinyl butyral coating.
[0021] Compared with the prior art, the beneficial effects of this utility model are:
[0022] 1. This utility model, by setting up a stress dispersion component, effectively disperses stress and reduces the risk of plate deformation through a wave-shaped titanium-nickel alloy stress dispersion strip. Its strength and toughness can withstand large stresses. The synergistic effect of eight groups makes stress dispersion more uniform. The combination of reinforcing ribs and buffer pads enhances structural stability and improves bending and compressive strength. The buffer pads absorb impact energy, reduce deformation caused by external impacts, ensure system stability, and improve deformation resistance. This component can also improve the service life of the plate, make it adaptable to complex environments, reduce damage during long-term use, and enhance its ability to withstand dynamic loads.
[0023] 2. This utility model, through the setting of reinforcement components, fixes the first reinforcing mesh composed of FRP strips and the reinforcement layer with resin adhesive, enhancing the in-plane deformation resistance of the board and keeping it stable when subjected to in-plane forces. The high-density fiberboard material and rubberwood base of the first reinforcement layer provide good support and ensure overall strength. The second reinforcing mesh and the second reinforcement layer further enhance the structural strength, making the board sturdy and durable. The bottom waterproof layer and the top waterproof layer form a double-layer waterproof protection, effectively preventing water erosion, avoiding moisture deformation and rot, extending service life, and ensuring normal use in humid and other complex environments. Attached Figure Description
[0024] Figure 1 This is a schematic diagram of the overall appearance structure of this utility model;
[0025] Figure 2 This is a schematic diagram of the overall internal structure of this utility model;
[0026] Figure 3 This is a schematic diagram of the combined structure of the plate body, wear-resistant layer, waterproof layer and stress dispersion component of this utility model;
[0027] Figure 4 This is a schematic diagram of the horizontally integrated disassembled structure of this utility model;
[0028] Figure 5 This is a schematic diagram of the stress dispersion component structure of this utility model;
[0029] Figure 6 This is a schematic diagram of the reinforcement component structure of this utility model.
[0030] The following are the labeling elements in the diagram: 1. Board body; 2. First connector; 3. Second connector; 4. Wear-resistant layer; 5. Top waterproof layer; 6. Stress dispersion assembly; 601. Stress dispersion layer; 602. Stress dispersion strip; 603. Reinforcing rib; 604. Fixing bolt; 605. Buffer pad; 7. Reinforcement assembly; 701. First reinforcement layer; 702. First reinforcing mesh; 703. Rubberwood base layer; 704. Second reinforcing mesh; 705. Second reinforcement layer; 8. Bottom waterproof layer. Detailed Implementation
[0031] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0032] Please see Figure 1-6 As shown, this utility model provides a technical solution: an extended and deformation-resistant rubberwood board, including a board body 1, a first connector 2 on the left side of the board body 1, a second connector 3 on the right side of the board body 1, a wear-resistant layer 4 installed on the upper surface of the board body 1, a top waterproof layer 5 installed on the inner side of the wear-resistant layer 4, a stress dispersion component 6 installed below the top waterproof layer 5, the stress dispersion component 6 including a stress dispersion layer 601 installed below the top waterproof layer 5, stress dispersion strips 602 installed on the surface of the stress dispersion layer 601, a reinforcement component 7 installed on the inner side of the board body 1, the reinforcement component 7 including a first reinforcement layer 701 installed on the inner side of the board body 1, and a first reinforcing mesh 702 installed on the lower inner side of the board body 1.
[0033] Furthermore, the board body 1 and the first connector 2 are fixedly connected. The wear-resistant layer 4 is made of melamine-impregnated paper, and the top waterproof layer 5 uses polyurethane waterproof paint. The first connector 2 is located at the lower left side of the board body 1, and the second connector 3 is located at the upper right side of the board body 1. In use, the two board bodies 1 can be spliced together by connecting the first connector 2 and the second connector 3 to ensure a tight splicing of the board bodies 1. The wear-resistant layer 4 is made of melamine-impregnated paper, which has excellent wear resistance and can effectively resist the friction of external objects on the surface of the board. The top waterproof layer 5 uses polyurethane waterproof paint, which has good waterproofness and adhesion and can effectively prevent water penetration.
[0034] Furthermore, the stress dispersion layer 601 is fixedly connected to the top waterproof layer 5 by high-temperature resistant adhesive. The stress dispersion strips 602 are wavy and made of titanium-nickel alloy. There are eight sets of stress dispersion strips 602. When the plate body 1 is subjected to external force, the stress dispersion strips 602 can disperse the stress. The titanium-nickel alloy stress dispersion strips 602 have good strength and toughness and can withstand large stress. The setting of eight sets of stress dispersion strips 602 makes the stress dispersion more uniform.
[0035] Furthermore, a reinforcing rib 603 is provided below the stress dispersion layer 601, and a fixing bolt 604 is installed on the inner side of the reinforcing rib 603. A buffer pad 605 is provided below the reinforcing rib 603. The reinforcing rib 603 is fixedly connected to the buffer pad 605 by the fixing bolt 604. The reinforcing rib 603 is composed of longitudinal and transverse reinforcing ribs 603. In use, it is fixed to the rubberwood base layer 703 below by the fixing bolt 604, while the buffer pad 605 plays a shock absorption and buffering role, reducing the risk of board deformation caused by external impact and ensuring the stability of the entire reinforcement system.
[0036] Furthermore, a rubberwood base layer 703 is provided below the first reinforcing mesh 702, the first reinforcing layer 701 is made of high-density fiberboard, and the first reinforcing mesh 702 is composed of FRP strips. The first reinforcing mesh 702 composed of FRP strips is fixed to the first reinforcing layer 701 and the second reinforcing layer 705 by a special resin adhesive, which enhances the board's resistance to deformation in the plane.
[0037] Furthermore, a second reinforcing mesh 704 is provided below the rubberwood base layer 703, and a second reinforcing layer 705 is provided below the second reinforcing mesh 704. The second reinforcing mesh 704 is fixedly connected to the second reinforcing layer 705 by a resin adhesive. The resin adhesive has good bonding performance, which can ensure a firm connection between the second reinforcing mesh 704 and the second reinforcing layer 705, thereby further enhancing the structural strength of the board.
[0038] Furthermore, a bottom waterproof layer 8 is provided below the second reinforcing layer 705. The bottom waterproof layer 8 uses a polyvinyl butyral coating. The polyvinyl butyral coating has good waterproof performance and can prevent moisture from penetrating into the interior of the board from the bottom, further enhancing the waterproof performance of the board, extending the service life of the board, and enabling the board to better adapt to humid environments.
[0039] Working principle: The device is installed in the working position. When it is necessary to lengthen the rubberwood board, the second connecting piece 3 of two board bodies 1 is spliced with the first connecting piece 2 of another board. The mortise and tenon structure tightly connects the two boards, thus increasing the board length. When the board body 1 is subjected to external force, the stress is first transmitted to the wear-resistant layer 4 and the top waterproof layer 5. Since the stress dispersion layer 601 is fixedly connected to the top waterproof layer 5, the stress is further transmitted to the stress dispersion layer 601. At this time, the stress dispersion strips 602 begin to function, dispersing the stress to each strip 602, reducing localized stress concentration in the board. (Titanium-nickel alloy...) The stress-dispersing strips 602, made of gold, possess excellent strength and toughness, allowing them to withstand significant stress. The synergistic effect of eight sets of stress-dispersing strips 602 ensures more uniform stress distribution, effectively reducing the risk of deformation of the board due to stress concentration. The reinforcing ribs 603, composed of longitudinal and transverse reinforcing ribs 603, are fixedly connected to the underlying buffer pads 605 via fixing bolts 604 and secured to the rubberwood base layer 703. The reinforcing ribs 603 enhance the structural strength of the board, improving its bending and compressive strength, allowing the board to better maintain its shape under external forces. The buffer pads 605 act as shock absorbers, absorbing some of the impact force when the board is subjected to external forces. Impact energy is reduced to minimize the risk of board deformation caused by external impacts, ensuring the stability of the entire reinforcement system and further improving the board's resistance to deformation. Inside the board, the first reinforcement layer 701 is made of high-density fiberboard, providing excellent support. The first reinforcing mesh 702, composed of FRP strips, is fixed to the first reinforcement layer 701 and the second reinforcement layer 705 with a special resin adhesive, enhancing the board's resistance to deformation in the plane. The rubberwood base layer 703, as the main load-bearing component of the board, provides a fundamental guarantee for the overall strength and stability of the board due to its excellent mechanical properties. The second reinforcing mesh 704 and the second reinforcement layer 705 are bonded together with resin. The adhesive firmly bonds the boards, further enhancing their structural strength and making them more robust and durable, capable of withstanding greater loads and external forces. The bottom waterproof layer 8 uses a polyvinyl butyral coating, whose excellent waterproof performance prevents moisture from seeping into the board from below. Together with the top waterproof layer 5, it forms a double-layer waterproof protection, further enhancing the board's waterproof performance. Even in humid environments, it effectively prevents moisture from eroding the board, avoiding problems such as deformation and rot caused by dampness, thus extending the board's service life and ensuring its normal use in various environments. This completes the process of using a rubberwood board that is extended and resistant to deformation.
[0040] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. An extended, deformation-resistant rubberwood board, comprising a board body (1), characterized in that: A first connector (2) is provided on the left side of the plate body (1), a second connector (3) is provided on the right side of the plate body (1), a wear-resistant layer (4) is installed on the upper surface of the plate body (1), a top waterproof layer (5) is installed on the inner side of the wear-resistant layer (4), a stress dispersion component (6) is provided below the top waterproof layer (5), the stress dispersion component (6) includes a stress dispersion layer (601) installed below the top waterproof layer (5), a stress dispersion strip (602) is installed on the surface of the stress dispersion layer (601), a reinforcement component (7) is installed on the inner side of the plate body (1), the reinforcement component (7) includes a first reinforcement layer (701) installed on the inner side of the plate body (1), and a first reinforcing mesh (702) is provided below the inner side of the plate body (1).
2. The extended, deformation-resistant rubberwood board according to claim 1, characterized in that, The plate body (1) and the first connector (2) are fixedly connected. The wear-resistant layer (4) is made of melamine impregnated paper. The top waterproof layer (5) is made of polyurethane waterproof paint.
3. The extended, deformation-resistant rubberwood board according to claim 1, characterized in that, The stress dispersion layer (601) is fixedly connected to the top waterproof layer (5) by high-temperature resistant adhesive. The stress dispersion strip (602) is wavy and made of titanium-nickel alloy, and is provided in eight sets.
4. The extended, deformation-resistant rubberwood board according to claim 1, characterized in that, A reinforcing rib (603) is provided below the stress dispersion layer (601), and a fixing bolt (604) is installed on the inner side of the reinforcing rib (603). A buffer pad (605) is provided below the reinforcing rib (603), and the reinforcing rib (603) is fixedly connected to the buffer pad (605) by the fixing bolt (604).
5. The extended, deformation-resistant rubberwood board according to claim 1, characterized in that, A rubberwood base layer (703) is provided below the first reinforcing mesh (702), the first reinforcing layer (701) is made of high-density fiberboard, and the first reinforcing mesh (702) is composed of FRP strips.
6. The extended, deformation-resistant rubberwood board according to claim 5, characterized in that, A second reinforcing mesh (704) is provided below the rubberwood base layer (703), and a second reinforcing layer (705) is provided below the second reinforcing mesh (704). The second reinforcing mesh (704) is fixedly connected to the second reinforcing layer (705) by a resin adhesive.
7. The extended, deformation-resistant rubberwood board according to claim 6, characterized in that, A bottom waterproof layer (8) is provided below the second reinforcing layer (705), and the bottom waterproof layer (8) is made of polyvinyl butyral coating.