KR20190036228A - Apparatus for blocking transfer of structural noise from hydraulic system for gun of warship - Google Patents

Abstract

The present invention relates to a structure noise transfer prevention device of a hydraulic system for guns of a warship. The present invention, capable of preventing noise generated from a hydraulic system on the deck of a warship from being delivered to the deck while supporting the hydraulic system, includes: a plurality of lower elastic mounts placed on the deck at a distance from each other; a lower plate supported by the lower elastic mounts to be separated from the deck, and maintaining level; a plurality of upper elastic mounts installed on the lower plate at a distance from each other; and an upper plate supported by the upper elastic mounts to be separated from the lower plate, maintaining level, and supporting the hydraulic system. According to the present invention, since the structure noise transfer prevention device includes upper and lower plates of a double deck structure supported by elastic mounts, the device is capable of minimizing the influence of a structure noise caused by noise or vibration as well as satisfying MIL-STD-740-2 which is structure noise standards, and moreover, preventing a loss caused by an unbalanced alignment between a motor and a pump.

Description

TECHNICAL FIELD [0001] The present invention relates to a structural noise blocking system for a hydraulic system,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a noise cancellation device and, more particularly, to a noise cancellation device that prevents vibration and noise generated in a ship installed on a deck of a ship from being transmitted to other peripheral equipment through a deck, To a structure noise cancellation device.

For example, guns operated in traps such as Aegis or Naval-class frigates are equipped with high-specification motors and pumps in order to drive the guns into compact, compact hydraulic systems due to the characteristics of the weapon system. These motors and pumps are designed to have high output power, which means that they generate very loud noises and vibrations during operation, and the generated noise or vibration may spread around the deck and adversely affect other equipment.

On the other hand, in the conventional case, since the deck of the traps is structurally thick, the noise or vibration is absorbed to some extent by the deck itself, but as the thickness of the deck decreases to 10 mm or less due to the weight reduction and cost reduction of the traps, And measures for blocking movement of vibration are required.

As part of this measure, the traps manufacturer has applied the structural noise standard MIL-STD-740-2 to all the equipment installed in the traps. It is needless to say that the hydraulic system for driving the ship must also be designed to satisfy the structural noise standard.

Korean Patent Laid-Open No. 10-2010-0071583 (dustproof oil damper mount) Korean Registered Utility Model No. 20-0404398 (floor structure of a building)

The present invention has been made in order to solve the above problems, and it is an object of the present invention to minimize the influence of noise caused by noise or vibration, satisfy the structural noise standard MIL-STD-740-2, And also to prevent a loss caused by an inconsistency of a noise caused by an alignment error.

In order to accomplish the above object, the present invention provides a structure-noise-transfer-blocking device for a cannon-driven hydraulic system in which a noise generated in the hydraulic system is transmitted to a deck in a state of being supported by a hydraulic system disposed on a deck of a ship. A plurality of lower elastic mounts spaced apart from each other above the deck; A lower plate supported by the lower elastic mount and spaced apart from the deck to maintain a horizontal position; A plurality of upper elastic mounts spaced apart from each other on an upper portion of the lower plate; And an upper plate which is supported by the upper elastic mount and is spaced apart from the lower plate and is horizontal and supports the hydraulic system.

The lower plate and the upper plate are steel plates having a predetermined thickness, and the upper plate has a relatively smaller area than the lower plate.

Further, the lower elastic mount includes: A plurality of support plates closely attached to the upper portion of the deck; a vibration-proof rubber fixed to the upper portion of the support plate; a cover partially receiving and protecting the vibration-proof rubber; And means for controlling the operation of the apparatus.

In addition, the lower portion of the anti-vibration rubber may further include second fixing means for fixing the support plate and the anti-vibration rubber to the deck.

Further, the second fixing means comprises: And an anchor nut connected to the male and female threads at a lower portion of the deck.

Further, the upper elastic mount comprises: A cover for partially receiving and protecting the anti-vibration rubber, a cover for covering the upper plate and a position of the anti-vibration rubber against the upper plate, And a second fixing means for fixing the support plate to the lower plate.

The first fastening means may include a mounting bolt threaded downward through the upper plate and the cover to thread the fastening rubber to the anti-vibration rubber.

Further, the second fixing means comprises: And a support plate bolt for fixing the support plate to the lower plate.

Further, the upper elastic mount and the lower elastic mount are vertically arranged in the vertical direction.

Since the structure noise cancellation apparatus of the present invention has the upper and lower plates of the double deck structure horizontally supported by the elastic mount, the influence of the structural noise due to noise or vibration is minimized, It satisfies the structural noise standard MIL-STD-740-2, and can prevent the loss caused by the mismatch of the alignment between the motor and the pump.

FIG. 1 is a side view for explaining the construction and operation of the structure noise cancellation device of a cannon-driven hydraulic system according to an embodiment of the present invention.
FIG. 2 is a plan view showing the upper plate and the lower plate shown in FIG. 1 separately.
3 is a cross-sectional view showing the internal structure of the upper elastic mount and the lower elastic mount shown in FIG.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a side view for explaining the construction and operation of the structural noise transfer blocking device 20 of a hammer drive hydraulic system according to an embodiment of the present invention. 2 is a sectional view showing the internal configuration of the upper elastic mount 25 and the lower elastic mount 27 shown in FIG.

Basically, the structural noise transfer blocking device 20 according to the present embodiment prevents the vibration or noise generated in the noise generating portion disposed on the deck deck 17 of the vessel from spreading around the deck as a medium . The noise generating unit in the present embodiment is the hydraulic system 11. In addition, the structure noise refers to the noise generated by the vibration transmitted through the solid.

As shown, the structural noise transfer blocking device 20 according to the present embodiment includes a plurality of lower elastic mounts 27, a lower plate 23, Mount (25), and top plate (21).

The lower elastic mount 27 horizontally supports the lower plate 23 and the upper elastic mount 25 supports the upper plate 21 horizontally.

The lower elastic mount 27 includes a plurality of support plates 27d which are in close contact with the upper surface of the deck 17, a vibration proof rubber 27c placed on the support plate 27d, A first fixing means for fixing the cover 27b and the vibration proof rubber 27c to the lower plate 23 and a second fixing means for fixing the foot plate 27d to the deck 17 And a second fixing means for fixing the vibration proof rubber 27c.

The support plate 27d closely contacts the upper surface of the deck 17 and is firmly fixed to the deck 17 through the support plate bolt 27f as a metal plate having a predetermined thickness for supporting the vibration proof rubber 27c.

The vibration-proof rubber 27c absorbs the structural noise coming from the upper part and has a shape of a cone, and the bottom surface is in contact with the support plate 27d. A plurality of fastening bolts (not shown) for fixing the vibration proof rubber 27c to the support plate 27d are used. The size and size of the anti-vibration rubber 27c can be variously changed as needed.

The cover 27b is a cylindrical member that opens downward, and partially covers and protects the vibration-proof rubber 27c. It is a matter of course that the lower end of the cover 27b should be spaced from the deck 17. The vibration-proof rubber 27c is received in the cover 27b and protected from external impact. The cover 27b may be made of metal or plastic.

The first fixing means serves to fix a combination of the cover 27b and the vibration proof rubber 27c to the lower portion of the lower plate 23 and includes a connecting bolt 27a.

The connecting bolt 27a is a part screwed to the anti-vibration rubber 27c in a state of being supported by a bolt hole 23a formed in the lower plate 23. As the anti-vibration rubber 27c is screwed into the connecting bolt 27a, it is firmly held on the lower plate 23. In some cases, a nut (not shown) engaging with the connecting bolt 27a may be fixed to the upper end of the vibration-proof rubber 27c.

The second fixing means is for fixing the lower elastic mount 27 to the deck 17 and includes a male screw rod 27e and an anchor nut 27f. The male and female rods 27e are downwardly pierced through the support plate 27d and the deck 17 in a state where the upper end thereof is fixed to the vibration-proof rubber, and have male threads at the outer peripheral surface thereof. Needless to say, the lower end of the male and female bar 27e protrudes below the deck 17.

The anchor nut 27f is screwed to the male or female bar 27e at the lower part of the deck 17 and serves to tightly fix the vibration rubber 27c to the upper surface of the deck 17. This means that the hole for inserting the male and female rods 27e must be formed in the deck 17 in order to install the structural noise transfer blocking device 20 of the present embodiment. When the anchor nut 27f is unscrewed from the male or female rod 27e, the structure noise cancellation device 20 can be lifted from the deck 17.

The lower plate 23 is a steel plate having a predetermined thickness and is supported by a plurality of lower elastic mounts 27 so as to be spaced from the deck 17 and kept horizontal. The lower plate 23 serves as a pedestal for supporting a plurality of upper elastic mounts 25 disposed thereon.

The upper elastic mount 25 includes a plurality of support plates 25d closely contacting the upper surface of the lower plate 23, a vibration proof rubber 25c fixed to the support plate 25d, A first fixing means for fixing the positions of the cover 25b and the vibration proof rubber 25c with respect to the upper plate 21 and a second fixing means for fixing the bottom plate 25d to the bottom plate 25b, (23).

The support plate 25d and the vibration proof rubber 25c have the same shape as the support plate 27d and the vibration proof rubber 27c included in the lower elastic mount 27. [ The support plates 25d and 27d are in the form of ellipses extending in opposite directions with the vibration-proof rubber 27c as a center and the upper support plate 25d and the lower support plate 27d are arranged in directions orthogonal to each other .

The support plate 25d is fixed to the lower plate 23 by the second fixing means, that is, the support plate bolt 25f. Naturally, when the base plate bolt 25f is disassembled, the vibration proof rubber 27c can be separated from the lower plate 23. [

Further, the cover 25b is a protective casing opened downward to partially cover the vibration-proof rubber 25c. The anti-vibration rubber 25c is protected from external impact while being accommodated in the cover 25b.

The first fixing means includes an elastic mount fixing hole 21a formed in the upper plate 21 and a mounting bolt 25a threaded downward through the cover 25b and screwed to the vibration proof rubber 25c. A nut (not shown) for engaging with the mounting bolt 25a may be fixed to the upper end of the vibration-proof rubber 25c.

In addition, as described above, the second fixing means is for tightly fixing the support plate 25d to the upper surface of the lower plate 23, and includes a plurality of support plate bolts 25f. The bottom plate bolt 25f passes through the bottom plate 25d and is screwed to the bottom plate 23.

The upper plate 21 is a steel plate having a predetermined thickness as in the case of the lower plate 23, and is held horizontally while being supported by a plurality of upper elastic mounts 25.

In particular, the upper elastic mount 25 and the lower elastic mount 27 are arranged vertically up and down. That is to say, the center axis of the mounting bolt 25a and the connecting bolt 27a coincide with each other and perpendicular to the upper surface of the deck 17.

The upper plate 21 is supported by a vertical laminate composed of the lower vibration damping rubber 27c, the lower plate 23 and the upper vibration damping rubber 25c, for example, there is no partial stiction. That is, the motor 13, the pump 15, the hydraulic system 11, and the like disposed on the upper plate 21 are stably supported on the upper plate 21.

If the upper plate 21 is lowered, an alignment mismatch between the motor 13 and the pump 15 may occur. In other words, a bending force is applied to the drive shaft of the motor 13 and the driven shaft of the pump. When the drive shaft of the motor 13 is finely eccentric due to the bending force, it is natural that the generated noise is further increased. However, since the upper plate 21 receives a strong supporting force and is kept horizontal at all times, there is no occurrence of an aline inconsistency.

3, the width of the upper plate 21 is relatively smaller than the width of the lower plate 23 in the structural noise transfer blocking apparatus 20 according to the present embodiment.

FIG. 3 is a plan view showing the upper plate and the lower plate shown in FIG. 1 separately.

As shown in the figure, the upper plate 21 has a size that can be included in an inner region of the lower plate 23. The reason for this construction is to maintain the accessibility to the upper elastic mount 25 satisfactorily so as to facilitate the maintenance.

When the hydraulic system 11 installed in the structural noise transfer blocking device 20 operates, the structural noise coming from the hydraulic system 11 spreads horizontally on the upper plate 21, And is firstly absorbed into the vibration-proof rubber 25c.

The residual structure noise that is not absorbed by the vibration-proof rubber 25c spreads in the horizontal direction on the lower plate 23 and moves to the vibration-proof rubber 27c of the lower elastic mount 27 so that almost all of the noise is absorbed. It goes without saying that the structural noise not absorbed by the vibration-proof rubber 27c satisfies the structural noise standard MIL-STD-740-2.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Hydraulic system
13: motor 15: pump
17: Deck 20: Structural noise transfer blocking device
21: upper plate 21a: elastic mount fixing hole
23: Lower plate 23a: Bolt hole
25: upper elastic mount 25a: mounting bolt
25b: cover 25c: anti-vibration rubber
25d: Base plate 25f: Base plate bolt
27: lower elastic mount 27a: connecting bolt
27b: cover 27c: anti-vibration rubber
27d: base plate 27e:
27k: Base plate bolt 27f: Anchor nut

Claims (9)

A system for preventing noise generated in the hydraulic system from being transmitted to a deck while being supported by a hydraulic system disposed on a deck of a ship,
A plurality of lower elastic mounts spaced apart from each other on top of the deck;
A lower plate supported by the lower elastic mount and spaced apart from the deck to maintain a horizontal position;
A plurality of upper elastic mounts spaced apart from each other on an upper portion of the lower plate;
And an upper plate supported by the upper elastic mount and spaced apart from the lower plate to maintain the horizontal and support the hydraulic system. The method according to claim 1,
Wherein the lower plate and the upper plate are steel plates having a certain thickness, and the upper plate has a relatively smaller area than the lower plate. The method according to claim 1,
The lower elastic mount comprises:
A plurality of foot plates closely attached to the upper portion of the deck,
An anti-vibration rubber fixed to an upper portion of the support plate,
A cover that partially receives and protects the anti-vibration rubber,
And a first fixing means for fixing the cover and the vibration-proof rubber to the lower plate. The method of claim 3,
And a second fixing means for fixing the support plate and the vibration-proof rubber to the deck, further comprising a lower fixing unit at the lower portion of the vibration-proof rubber. 5. The method of claim 4,
The second fixing means comprises:
A male screw rod which passes through the bottom plate and the deck in a state where an upper end portion thereof is fixed to the vibration-
And an anchor nut coupled to the male and female threads at the bottom of the deck. The method according to claim 1,
The upper elastic mount comprises:
A base plate having a predetermined thickness fixedly attached to the upper surface of the lower plate,
An anti-vibration rubber which is coupled to the upper surface of the support plate,
A cover that partially receives and protects the anti-vibration rubber,
First fixing means for fixing the position of the cover and the vibration-proof rubber to the upper plate,
And second fixing means for fixing the foot plate to the lower plate. The method according to claim 6,
Wherein the first fixing means comprises:
And a mounting bolt threaded downward through the top plate and the cover to the anti-vibration rubber. The method according to claim 6,
The second fixing means comprises:
And a support plate bolt for fixing the support plate to the lower plate. The method according to claim 1,
Wherein the upper elastic mount and the lower elastic mount are disposed vertically up and down.

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