A method for forming a liquid rubber composite node with a damping through hole and the node
A technology of liquid rubber and damping hole, which is applied in the direction of shock absorber-spring combination, spring/shock absorber design features, shock absorber, etc., can solve difficult problems such as realization, and achieve product quality assurance, large axial stiffness, The effect of expanding the volume space
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Embodiment 1
[0040] Embodiment 1: as figure 1 and figure 2 As shown, a method of forming a liquid rubber composite node with an intermediate damping hole, which is to add an intermediate spacer 3 between the outer casing 1 and the mandrel 2, and vulcanize and bond the intermediate spacer 3 and the mandrel 2 through rubber 4 Together, the integrated intermediate spacer and the mandrel are assembled into the outer casing 1; the mandrel 2 is provided with a damping through hole passing through the mandrel 2, and the middle spacer 3 is hollowed out to form multiple spaces. After vulcanization, the rubber 4 and the multiple spaces are used to form a plurality of liquid cavities 5 that are independent of each other. Liquids (not shown in the figure) are arranged in the plurality of liquid cavities 5 and pass through the plurality of liquid cavities 5. The damping through holes 6 communicate with each other. The liquid rubber composite joint formed by the above method can provide smaller radia...
Embodiment 2
[0055] Embodiment 2: as Figure 9 As shown, compared with Example 1, the difference is that in order to enable the liquid rubber to provide nonlinear stiffness characteristics, this embodiment adopts the following scheme: the inner peripheral arc surface of the arc-shaped cover plate 7 in this embodiment No bumps are set on the top, but a mandrel bump 211 is set on the mandrel 2, and the rubber 4 is covered on the mandrel 2 and the mandrel bump 211 and formed along it. Under the action of load, the arc-shaped cover plate 7 first contacts the rubber 4 located in the liquid cavity, and the node begins to provide nonlinear stiffness characteristics. The contact forms a hard stop limit protection function. In this embodiment, there are corresponding protruding mandrel protrusions 211 on the outer peripheral surface of the mandrel 2 corresponding to the two arc-shaped cover plates 7, and the two mandrel protrusions 211 are respectively located in the two liquid cavities. 5 in.
Embodiment 3
[0056] Embodiment 3: as Figure 10 As shown, compared with Embodiment 1, the difference is that in order to enable the liquid rubber to provide nonlinear stiffness characteristics, this embodiment adopts the following scheme: on the arc-shaped cover plate 7 and the mandrel 2 in this embodiment No projections are provided, and only rubber projections 415 protruding toward the arc-shaped cover plate 7 are provided on the rubber 4 covering the outer peripheral surface of the mandrel 2 in the liquid cavity. When using the arc-shaped cover plate 7 and the rubber projection 415 When in contact, the node begins to provide a non-linear stiffness characteristic, but in this embodiment, the node has no hard stop limit protection function. In this embodiment, the two rubber bumps 415 are respectively located in the two liquid cavities 5 .
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