JPH0687749U - Active mount - Google Patents

Abstract

(57) [Summary] [Purpose] To effectively damp vibrations in the middle and high frequencies (idle vibrations, etc.) without increasing the size and capacity of the actuator. A main liquid chamber 12 is formed in a portion surrounded by an actuator 5, a support spring 2 and a partition wall 3, while a sub liquid chamber 1 is formed in a portion surrounded by a diaphragm 4 and a partition wall 3.
3 is formed. The partition wall 3 is partitioned by the main liquid chamber 12 and the first displacement member 17, and the sub liquid chamber 13 and the second displacement member 1 are divided.
Auxiliary liquid chamber 14 divided by 8 and main / sub liquid chamber 1
A first orifice 19 that connects between 2 and 13 and an auxiliary
A second orifice 20 that communicates between the sub liquid chambers 14 and 13 is provided. Vibrations in the low frequency range are damped by the first orifice 19, and the second orifice 20 and the actuator 5
Thus, the vibration in the middle / high frequency range is damped, and the actuator 5 damps the vibration in the frequency range exceeding the resonance frequency of the second orifice 20.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a vibration control device for supporting a vibration body such as an automobile engine in a vibration-proof manner, and more particularly to an active mount effective for attenuating vibrations in a middle or high frequency range (idle vibration, etc.).

[0002]

[Prior art and its problems]

 Generally, in an automobile engine, a large amplitude (± 0.25 mm) vibration is generated when idling and a small amplitude (± 0.05 mm) vibration is generated when the vehicle is running, so these vibrations can be effectively damped. There is a strong demand for anti-vibration devices. In particular, considering the traffic conditions in Japan, where traffic congestion frequently occurs, it is an important issue to completely eliminate the large-amplitude idle vibration.

As a vibration isolation device capable of attenuating such vibration, for example, the vibration isolation device disclosed in Japanese Patent Laid-Open No. 3-24338 is already known, and this vibration isolation device is a so-called The active mount damps low-frequency vibrations (shock vibrations, etc.) due to liquid column resonance when liquids move between the working chamber and the pressure adjusting chamber via the buffer holes, and By driving the diaphragm, vibrations in the mid- and high-frequency range (idle vibrations, etc.) are damped by generating pulsation in the opposite phase to the vibration input to the liquid in the working chamber.

However, since the amount of energy generated by the electric system is small in the idling rotation range, it is necessary to suppress the energy consumption as a whole as well as the energy consumption of the actuator. Therefore, even in the above active mount, the diaphragm of the actuator must be downsized and the magnet system for driving the diaphragm must be downsized, which limits the driving range of the diaphragm to a small range. , The pulsation sufficient to damp the input vibration cannot be applied to the liquid in the working chamber.

The present invention solves the above-mentioned problems of the conventional one, and increases the size and capacity of the actuator by combining the resonance of the orifice with the change of the hydraulic pressure of the actuator. It is an object of the present invention to provide an active mount that can sufficiently damp vibrations in the middle and high frequencies (idle vibrations, etc.) without doing so.

[0006]

[Means for solving problems]

 In order to solve the above-mentioned problems, the present invention connects a case to the upper surface side of a partition wall via a support spring, and provides a driving member and a driven member that can be driven by the driving member in the case. A main liquid chamber is formed in a portion surrounded by the driven member, the support spring, and the partition wall, and a sub liquid chamber surrounded by a diaphragm is formed on the lower surface side of the partition wall. And a supplementary liquid chamber that is partitioned from the main liquid chamber via the first displacement member and is partitioned from the auxiliary liquid chamber via the second displacement member. , Means for providing a second orifice for communicating between the auxiliary liquid chamber and the auxiliary liquid chamber.

[0007]

[Action]

 By adopting the above-mentioned means, the present invention allows the liquid to move between the main liquid chamber and the sub liquid chamber via the first orifice up to the resonance frequency range of the first orifice. The liquid column resonance damps the input vibration. When the resonance frequency of the first orifice is exceeded, the liquid column inertia becomes large, so that the liquid does not move between the main and sub liquid chambers via the first orifice. Here, when the driven member is driven by the driving member, it is possible to give a pulsation having a phase opposite to the vibration input to the liquid in the main liquid chamber, but this alone can completely damp the vibration in this frequency range. I can't. Then, the input vibration causes the hydraulic pressure in the main liquid chamber to gradually rise, the first displacement member of the partition wall is displaced in accordance with the change in the hydraulic pressure in the main liquid chamber, and the auxiliary liquid chamber changes in volume. Then, due to the volume change of the auxiliary liquid chamber, the liquid in the auxiliary liquid chamber moves to the side of the auxiliary liquid chamber via the second orifice. The liquid column resonance when liquid moves between the auxiliary liquid chamber and the auxiliary liquid chamber through the second orifice makes it possible to absorb the load left by the driven member. Then, when the resonance frequency of the second orifice is exceeded, the liquid column inertia increases, so that the movement of the liquid between the auxiliary liquid chamber and the sub liquid chamber via the second orifice ceases, but the input vibration Since the amplitude of is gradually decreased, driving the driven member by the driving member can give sufficient pulsation to reduce the vibration input to the liquid in the main liquid chamber, and the dynamic spring can be reduced to almost zero. It can be a close value.

[0008]

【Example】

 An embodiment of the present invention shown in the drawings will be described below. 1 and 2 show an embodiment of an active mount according to the present invention, FIG. 1 is a schematic sectional view showing the whole, and FIG. 2 shows the relationship between the dynamic spring and the frequency of the one shown in FIG. FIG.

That is, the active mount has a cylindrical shape with an upper end closed, a case 1 in which a screw portion 1a is provided in the center of the upper surface, and a substantially cylindrical shape with one end connected to the lower end opening of the case 1. -Shaped support spring 2 made of rubber-like elastic material, a partition wall 3 connected to the other end of the support bar 2, a diaphragm 4 provided on the lower surface side of the partition wall 3, and an actuator 5 provided in the case 1. The main liquid chamber 12 is surrounded by the actuator 5, the support spring 2 and the partition wall 3, the auxiliary liquid chamber 13 is surrounded by the partition wall 3 and the diaphragm 4, and the auxiliary liquid chamber 14 is surrounded by the partition wall 3. Each of the liquid chambers 12, 13 and 14 is filled with an incompressible liquid such as water or oil.

The actuator 5 is connected to the inner surface of the case 1 via a spring member 15 made of a rubber-like elastic material, and has a lower surface facing the main liquid chamber 12 and made of a magnetizable material. It includes a vibrating plate 11 which is a driving member, and a driving member 6 which drives the vibrating plate 11.

The drive member 6 is fitted on the inner surface of the case 1 above the diaphragm 11 on the outer peripheral side, and also has a disk-shaped yoke 8 facing the diaphragm 11 with a predetermined gap therebetween. A substantially disk-shaped permanent magnet 10 mounted on the center of the surface of the yoke 8 facing the diaphragm 11 and a coil 9 mounted in the groove 8a of the yoke 8 at the peripheral edge of the permanent magnet 10. The coil 9 and the yoke 8 constitute an electromagnet 7, and the diaphragm 11 is driven by the cooperation of the electromagnet 7 and the permanent magnet 10 against the spring force of the spring member 15. It has become.

The diaphragm 4 is formed of a rubber-like elastic material and has a thin bowl shape. The peripheral edge of the diaphragm 4 is caulked to the lower surface side of the partition wall 3 with the peripheral edge of the bowl-shaped lid member 16. A screw portion 16a for connecting to the body side is provided in the central portion of the lid member 16.

The partition wall 3 has a substantially disk shape, and a through hole 3a penetrating from the upper surface side to the lower surface side is formed in the central portion, and the upper surface side opening portion (main liquid chamber 12 side) thereof. Is closed by a first displacement member 17 made of a rubber-like elastic material and having an appropriate spring constant, and the lower surface side opening (the sub liquid chamber 13 side) is made of a rubber-like elastic material having an appropriate spring constant. It is closed by the second displacement member 18, and the auxiliary liquid chamber 14 is formed between the displacement members 17 and 18.

The main liquid chamber 12 and the sub liquid chamber 13 are communicated with each other through a thin and long first orifice 19 formed in the partition wall 3. The auxiliary liquid chamber 14 and the auxiliary liquid chamber 13 are communicated with each other through a second orifice 20 which is thicker and shorter than the first orifice 19 formed in the partition wall 3. ing.

Next, the operation of the above-described one will be described with reference to FIG. First, the case 1 of the active mount configured as described above is connected to the engine side (not shown) via the screw portion 1a at the center of the upper surface side, and the lid member 16 is shown at the screw portion 16a in the center thereof. When connected to the body side and operating the engine, various vibrations are input to the case 1 from the engine.

[0016] Here, in advance, a desired frequency within 5～10H _Z resonance frequency of the first orifice 19 (during running) (e.g. 7H _Z), the resonance frequency of the second orifice 20 20 ~30H _Z ( If you set the desired frequency of idling) in (e.g., 23H _Z), in the frequency range of 0~7H _Z, between the main liquid chamber 12 and the auxiliary liquid chamber 13 through the first orifice 19 The liquids move freely, the hydraulic pressure in the main liquid chamber 12 does not rise, and the dynamic spring becomes equal to the support spring 2.

When the resonance frequency of the first orifice 19 is approached, the inertia of the liquid passing through the first orifice 19 causes a shift in the phase of movement of the liquid with respect to the input vibration, causing a shift in the mount. Fluid pressure causes pulsation. The pulsating increases gradually with increasing frequency, acting on the hydraulic rise opposite by vibration near resonance of 7H _Z, the effect of moving amount and the phase of the liquid reaches a peak becomes maximum. Therefore, by setting the resonance frequency of the first orifice 19 to a desired value, shock vibration during traveling can be effectively damped.

Further, 7H _Z in the frequency range of ～23H _Z, since the liquid column inertia of the first orifice 19 increases, the liquid between the main and auxiliary liquid chamber 12, 13 each other through the first orifice 19 No movement.

Here, the driven member 11 is driven by the driving member 6 of the actuator 5, that is, the diaphragm 11 is vibrated by the cooperation of the electromagnet 7 and the permanent magnet 10, and the liquid in the main liquid chamber 12 is vibrated. If a pulsation in the opposite phase to the vibration input to is generated, the load to be transmitted to the partition 3 side is absorbed due to the change in hydraulic pressure, but the change in hydraulic pressure due to the vibration of diaphragm 11 alone causes The load cannot be completely absorbed.

Therefore, due to the vibration input from the engine, the hydraulic pressure in the main liquid chamber 12 gradually rises, and the first displacement member 17 of the partition wall 3 bends accordingly, and the first displacement member 17 The volume of the auxiliary liquid chamber 14 changes according to the amount of bending of the liquid, and the liquid inside the auxiliary liquid chamber 14 moves to the side of the auxiliary liquid chamber 13 via the second orifice 20. Will be absorbed. The dynamic spring in this frequency range is the load generated by the displacement of the support spring 2 plus the load generated by the increase in the hydraulic pressure of the main liquid chamber 12.

When the resonance frequency of the second orifice 20 is approached, the inertia of the liquid passing through the second orifice 20 causes a shift in the phase of the movement of the liquid with respect to the input vibration, causing a shift in the mount. Fluid pressure causes pulsation. This pulsation gradually increases as the frequency increases, and in the vicinity of the resonance of 23H _Z , the pulsation acts in reverse to the hydraulic pressure increase due to the vibration, and the effect of the liquid movement amount and the phase reaches its peak. Therefore, by setting the resonance frequency of the second orifice 20 to a desired value, idle vibration or the like can be effectively damped.

Further, at a frequency range in excess of 23H _Z, since the liquid column inertia of the second orifice 20 is large, the auxiliary liquid chamber 14, the secondary liquid chamber 13 phase互間through the first orifice 19 Although the liquid does not move, the amplitude of the vibration input from the engine gradually decreases in this frequency range, so a change in the hydraulic pressure by the actuator 5 is sufficient. Therefore, by virtue of the cooperation of the electromagnet 7 and the permanent magnet 10 constituting the driving member 6, the diaphragm 11 which is a driven member is kept in a driving state, and the pulsation in the opposite phase to the input vibration is generated in the main liquid chamber 12. If it is generated in the liquid, the dynamic spring can be made to have a value close to 0, and by this, the generation of muffled sound in this frequency range can be prevented.

As described above, in the active mount according to this embodiment, by utilizing the liquid column resonance action of the first orifice 19 of the partition wall 3, it is possible to damp vibrations in a low frequency range, and By utilizing the liquid column resonance action of the second orifice 20 of the partition wall 3 and the change of the liquid pressure by the actuator 5, it is possible to damp vibrations in the middle and high frequency ranges and to resonate the second orifice 20. By using the actuator 5 in a frequency range exceeding the frequency, a low dynamic spring close to 0 can be obtained.

Therefore, the size of the diaphragm 11 that is the driven member of the actuator 5 is increased, and the size of the electromagnet 7 and the permanent magnet 10 that is the driving member that drives the diaphragm 11 is not increased. Even with No. 5, vibrations in the middle and high frequencies (idle vibrations, etc.) can be sufficiently dampened, and this can be effectively used in places where energy saving is required, such as automobile engines. become.

[0025]

[Effect of device]

 The present invention is configured as described above, so that in the low frequency range, the liquid column resonance action when liquid moves between the main and sub liquid chambers of the first orifice is used to improve Damping can be obtained, and shock vibrations and the like during traveling can be effectively damped. Further, in the middle and high frequency regions, the liquid column when the liquid moves between the auxiliary liquid chamber and the auxiliary liquid chamber via the second orifice due to the change in the liquid pressure of the main liquid chamber due to the driven member. By combining the resonance action, idle vibration and the like during idle rotation can be effectively damped. Further, in the frequency range exceeding the resonance frequency of the second orifice, the liquid column inertia becomes large, so that the movement of the liquid between the auxiliary liquid chamber and the auxiliary liquid chamber via the second orifice disappears, but Since the amplitude of the vibration that is generated gradually decreases, it is possible to give sufficient pulsation to attenuate the vibration that is input to the liquid in the main liquid chamber by keeping the driven member in the driven state. Therefore, the dynamic spring in this frequency range can be set to a value close to 0, and the generation of muffled noise can be completely prevented. In this way, the first orifice, the second orifice, and the driven member / driving member are selectively used according to the frequency, without increasing the size of the driven member and the capacity of the driving member. Therefore, even small-sized driven members and small-capacity driving members can sufficiently damp vibrations in the middle and high frequencies, which makes them effective for automobile engines that require energy savings. It has an excellent effect that it can be used.

[Brief description of drawings]

FIG. 1 is a schematic sectional view showing an entire embodiment of an active mount according to the present invention.

FIG. 2 is an explanatory diagram showing the relationship between the dynamic spring and the frequency of the one shown in FIG.

[Explanation of symbols]

 1 ... Case 1a ... Screw part 2 ... Support spring 3 ... Partition wall 3a ... Through hole 4 ... Diaphragm 5 ... Actuator 6 ... Driving member 7 ... Electromagnet 8 ... Yoke 8a ... Groove 9 ... ... Coil 10 ... Permanent magnet 11 ... Driven member (vibrating plate) 12 ... Main liquid chamber 13 ... Sub liquid chamber 14 ... Auxiliary liquid chamber 15 ... Spring member 16 ... Lid member 16a ... Screw part 17 ... 1st displacement member 18 ... 2nd displacement member 19 ... 1st orifice 20 ... 2nd orifice

Claims (1)

[Scope of utility model registration request] 1. The case (1) is connected to the upper surface side of the partition wall (3) through a support spring (2), and the case (1) is also connected.
A portion surrounded by a driving member (6) and a driven member (11) that can be driven by the driving member (6) and surrounded by the driven member (11), a support spring (2), and a partition wall (3). A main liquid chamber (12) is formed in the
A sub liquid chamber (13) surrounded by a diaphragm (4) is formed on the lower surface side of the first partition, and the partition wall (3) communicates between the main liquid chamber (12) and the sub liquid chamber (13). It is partitioned from the main liquid chamber (12) via the orifice (19) and the first displacement member (17), and is partitioned from the auxiliary liquid chamber (13) via the second displacement member (18). An active mount comprising an auxiliary liquid chamber (14) and a second orifice (20) communicating between the auxiliary liquid chamber (14) and the auxiliary liquid chamber (13).