JPH0222518Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a vibration isolator for underwater equipment, and more particularly to a vibration isolator for underwater equipment having a rotating shaft protruding from the inside into outside water.

[Conventional technology]

A conventional vibration isolator around a rotating shaft in underwater equipment is shown in FIG. 4, in which a bearing 2 mounted on a rotating shaft 1 is mounted in a bearing box 4 with a cap screw 5.

On the other hand, an elastic ring 7 formed by alternately stacking annular rubber 7a and an annular intermediate ring 7b formed of metal or the like is connected to
It is attached to a case 9 fixed to an outer shell 10.

The elastic ring 7 supports the bearing box 4 in vibration isolation via the bearing box support ring 8. Note that in the drawings, reference numerals 3 and 4a' indicate a bearing nut and a flange, respectively.

With the above-described configuration, the rotary shaft 1 is supported by the case 9 via the elastic ring 7, and transmission of vibrations of the rotary shaft 1 to the outer shell 10 is reduced.

[Problem that the invention attempts to solve]

However, in the conventional vibration isolating device as described above, since the elastic ring 7 is a non-linear spring, when the depth of use of the underwater equipment changes, the water pressure received at that time changes and the rubber 7a deforms. At the same time, the spring constant changes [see FIG. 3b], and the natural frequency of the system of the rotating shaft 1 and the elastic ring 7 changes, so there is a problem that sufficient vibration damping performance cannot be maintained.

In particular, as the depth increases, the spring constant k of the elastic ring 7 increases rapidly due to water pressure, and the elastic ring 7
becomes stiff, making it impossible to obtain a vibration-proofing effect.

This invention attempts to solve the above-mentioned problems, and takes into account the change in the spring constant of the elastic ring depending on the depth of use of underwater equipment, and maintains vibration isolation performance even when the depth of use changes. The purpose of the present invention is to provide a vibration isolating device for underwater equipment.

[Means for solving problems]

For this reason, the vibration isolator for underwater equipment of the present invention is designed to support the rotating shaft protruding from the inside of the underwater equipment into the outside water in a vibration-proof manner by installing an inner flange protruding from the outer periphery of the bearing portion of the rotating shaft. A first elastic ring made of a laminated material of an annular rubber and an intermediate ring is provided between the side surface and a tightening ring that is screwed into the wall of the underwater device, and a first elastic ring is provided between the outer surface of the flange and a tightening ring that is screwed into the wall of the underwater device. A second elastic ring made of the laminated material is provided between the bearing surface and the bearing part in a state where the first elastic ring and the second elastic ring are precompressed by the tightening ring. It is characterized by supporting.

[Effect]

In the above-mentioned vibration isolator for underwater equipment of the present invention, the first and second elastic rings are arranged in series and precompressed so as to sandwich the flange on the outer periphery of the bearing of the rotating shaft, so that the entire elastic ring is The spring constant of the system changes in stages to prevent vibration damping performance from deteriorating due to water pressure.

〔Example〕

Below, a vibration isolator for underwater equipment as an embodiment of the present invention will be explained with reference to the drawings. Fig. 1 is a longitudinal sectional view thereof, and Figs. 2 a, b, and c are views of its first and second elastic rings. FIG. 3 is an explanatory diagram schematically showing the operating state, and FIG. 3 shows changes in the spring constant of the vibration isolator of the present invention and the conventional vibration isolator.
Figure 3a is a graph showing how the spring constant changes when the elastic ring of the vibration isolator of the present invention is approximated to a linear spring, and Figure 3b shows how the spring constant changes in the conventional vibration isolator. The graph shown in FIG. 3c is a graph showing how the spring constant changes when the nonlinearity of the elastic ring of the device of the present invention is taken into account.

As shown in FIG. 1, a bearing 2 is attached by a bearing nut 3 to a rotating shaft 1 that protrudes from the inside of an underwater device into the outside water. The bearing 2 is fitted into a bearing box 4 having a flange 4a protruding from its outer periphery.
It is fixed with a holding screw 5.

On the other hand, a case 9 is fixed to the outer shell 10 of the underwater device, and a tightening ring 6 is screwed into the case 9. In order to support the bearing box 4 in a vibration-proof manner, the inner surface 4b of the flange 4a and the tightening ring 6
A first elastic ring 11 made of a laminated material formed by alternately stacking annular rubber 11a and annular intermediate rings 11b made of metal, resin, etc. is provided between the two.

Further, between the outer surface 4c of the flange 4a and the receiving surface 9a of the case 9, a ring 13 is interposed between the outer surface 4c of the flange 4a and the receiving surface 9a of the case 9. Similarly to the first elastic ring 11, a second elastic ring 12a and an intermediate ring 12b, each having a laminated structure, is provided through the ring 13. Two elastic rings 12 are provided.

The first elastic ring 11 and the second elastic ring 12 support the bearing box 4 in a pre-compressed state by the tightening ring 6.

Note that the spring constants of the first elastic ring 11 and the second elastic ring 12 are appropriately set by changing the materials, thicknesses, etc. of the rubbers 11a and 12a.

The vibration isolator for underwater equipment of the present invention is constructed as described above, and the principle of its operation is shown in Figures 2 and 3 a.
This is explained by:

Note that this principle of action holds true regardless of whether the spring is linear or nonlinear, so for the sake of simplicity, both the first elastic ring 11 and the second elastic ring 12 are approximated to linear springs. and explain.

Figure 2a shows the spring constant of the first elastic ring k ₁ ,
Their unloaded state is shown with its natural length as l ₁₀ , the spring constant of the second elastic ring as k ₂ , and its natural length as l ₂₀ . At this time, the force acting on point A
f ₀ is 0.

Note that the symbol A indicates the position of the flange 4a in FIG.

Thus, the device of the present invention is expressed as a series spring model.

When the first elastic ring 11 and the second elastic ring 12 are precompressed by the tightening ring 6 from the state shown in FIG. 2a, the state shown in FIG. 2b is obtained. At this time, the spring lengths are l ₁₁ and l ₂₁ , respectively. As shown here, it is precompressed by Δl by the tightening ring 6,
If A is displaced by x ₁ , the force f ₁ acting on point A is f ₁ = k ₁ x ₁ (1).

On the other hand, when f ₁ is expressed using k ₂ , f ₁ = k ₂ (Δl−x ₁ ) (2). In other words, external force (water pressure) is applied to the vibration isolator of this invention.
When the flange 4a is not acting, the flange 4a is
The force f ₁ is applied from both sides by the elastic ring 11 and the second elastic ring 12.

Figure 2c shows a state in which water pressure acts on the vibration isolator of the present invention and the displacement of A becomes Δl. Letting the spring lengths at this time be l ₁₂ and l ₂₂ , respectively, l ₂₀ = l ₂₂ ...(3) and l ₁₂ = l ₁₀ - Δl ...(4), so it acts on the first elastic ring. power
f ₂ is f ₂ =k ₁ Δl (5) and the second elastic ring is in a free state because it has its natural length.

That is, the water pressure at this time is equal to f ₂ , and a water pressure of k ₁ Δl is acting on the flange 4a.

Next, changes in the spring constant of the device of the present invention will be explained using the graph shown in FIG. 3a. Thin solid straight line a,
b and c are respectively f=(k ₁ +k ₂ )x, f=k ₂ x,
A graph of f=k ₁ x is shown. Note that f ₃ indicates the value of the following equation.

f ₃ = k ₂ Δl = (k ₁ + k ₂ ) x ₁ Now, using equations (1) and (2) above, k ₁ x ₁ = k ₂ (Δl−x ₁ ) ...(6) is obtained. It will be done.

Also, considering the external force (water pressure) F, regarding the displacement x at point A, when x=x ₁ , F=0...(7), and when x≦Δl, F=(k ₁ + k ₂ )( x−x ₁ ) ...(8), and when x=0, F ₀ =−(k ₁ +k ₂ )x ₁ .
Further, when x≧Δl, the second elastic ring 12 is released from compression, so the spring constant of the entire device becomes only k ₁ , and F=k ₁ x (9).

That is, the relationship between the external force F and the displacement of the flange 4a is as shown by the thick solid line in FIG. 3a.

Here, considering that the elastic ring is a nonlinear spring, the relationship between external force and displacement of flange 4a in a conventional vibration isolator is illustrated. As shown by the solid line in Fig. 3b, as the external force increases, The spring constant k (the slope of the tangent to the curve) of the elastic ring 7 increases rapidly, but in the device of the present invention, the spring constant k ₁ of the first elastic ring 11 and the spring constant k 2 of the second elastic ring ₁₂ is set appropriately so that k ₁ + k ₂ is approximately equal to the spring constant of the elastic ring 7 of the conventional device, as shown by the solid line in Figure 3c, even if the external force becomes large, the The spring constant does not increase rapidly.

The broken lines in FIGS. 3b and 3c show the relationship between F and x when the elastic ring is approximated as a linear spring.

In this way, in the device of the present invention, the first elastic ring 11 and the second elastic ring 12 are pre-compressed, so when using underwater equipment at shallow depths, it is possible to obtain almost the same vibration-proofing effect as conventional ones. In addition, even when used at a deep location, it is possible to prevent the vibration damping effect from being reduced due to a sudden increase in the spring constant of the elastic ring.

In addition, in the device of the present invention, a second flange may be provided protrudingly behind the flange 4a of the bearing box 4, and a third elastic ring may be provided between the inner surface of the flange and the case 9. Further, a large number of elastic rings may be similarly arranged.

In the device of the present invention, since the elastic rings 11 and 12 are arranged on both the front and rear sides of the flange 4a,
A vibration damping effect can be obtained in both the front and rear directions of the axis.

[Effect of idea]

As described in detail above, according to the vibration isolating device for underwater equipment of the present invention, in order to support the rotating shaft protruding from the inside of the underwater equipment into the outside water in a vibration-proof manner, the outer circumference of the bearing portion of the rotating shaft is protruded. A first elastic ring made of a laminated material of an annular rubber and an intermediate ring is provided between the inner surface of the provided flange and a tightening ring screwed onto the wall of the underwater device; A second elastic ring made of the laminated material is provided between the receiving surface of the underwater device wall, and the first elastic ring and the second elastic ring are pre-compressed by the tightening ring. It has a simple configuration that supports the above bearing part in the state of
Whether underwater equipment is used at a shallow or deep depth, the vibration isolation effect will not be reduced depending on the depth of use.
This has the advantage of providing a stable vibration-proofing effect.

[Brief explanation of the drawing]

Figures 1 and 2 show a vibration isolator for underwater equipment as an embodiment of the present invention. FIG. 3 is an explanatory diagram schematically showing the operating state of the elastic ring, and FIGS. 3a, b, and c show changes in the spring constant of the vibration isolator of the present invention and the conventional vibration isolator, respectively, Figure 3a is a graph showing how the spring constant changes when the elastic ring of the vibration isolator of the present invention is approximated to a linear spring, and Figure 3b shows how the spring constant changes in the conventional vibration isolator. Graph shown, 3rd
Figure c is a graph showing how the spring constant changes when the nonlinearity of the elastic ring of the device of the present invention is taken into account, and Figure 4 is a longitudinal sectional view of a conventional vibration isolator for underwater equipment. 1... Rotating shaft, 2... Bearing, 3... Bearing nut, 4... Bearing box, 4a... Flange, 4b
...Flange inner surface, 4c...Flange outer surface,
5...Press screw, 6...Tightening ring, 9...
... Case, 9a ... Reception surface, 10 ... Outer shell of underwater equipment, 11 ... First elastic ring, 11a ... Annular rubber, 11b ... Intermediate ring, 12 ... Second elastic ring, 12a ... ... Annular rubber, 12b ... Intermediate ring, 13 ... Ring, k ₁ , k ₂ ... Spring constant.

Claims (1)

[Scope of utility model registration request] In order to support the rotating shaft protruding from the inside of the underwater equipment into the outside water in a vibration-proof manner, the inner surface of a flange protruding from the outer periphery of the bearing of the rotating shaft is screwed into the wall of the underwater equipment. A first elastic ring made of a laminated material of an annular rubber and an intermediate ring is provided between the ring, and a second elastic ring made of the laminated material is provided between the outer surface of the flange and the receiving surface of the underwater equipment wall. An underwater device comprising an elastic ring, the first elastic ring and the second elastic ring supporting the bearing part in a pre-compressed state by the tightening ring. Vibration isolator for use.