JPS6158326B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an air suspension device for an automobile, and more particularly to an air suspension device for an automobile using a closed air circuit.

Conventional technology Conventional air suspension systems for automobiles have always used an open air circuit that supplies air from outside. The disadvantage is that there is a large energy loss because the energy is emitted to the For this reason, closed air circuits were used to replenish the used air as intake air for the compressor (for example,
issue).

Problems to be Solved by the Invention However, in the conventional closed air circuit, normally the air in the low pressure tank is compressed by a compressor and supplied to the high pressure tank, and when replenishing, the atmospheric pressure air supplied through the air replenishment device is first passed through the compressor. It was configured to compress and supply it to a low-pressure tank, and then to a high-pressure tank in the same way as normal. Therefore, since two tanks, a low-pressure tank and a high-pressure tank, are used, a large space is required, and it is difficult to install the tank in a small vehicle in particular.

SUMMARY OF THE INVENTION In view of the above-mentioned conventional drawbacks, the present invention aims to provide a compact and inexpensive air suspension system for automobiles that uses a single reservoir tank and can supply and discharge air using a compressor.

Measures to solve the problem A closed air circuit is configured with a reservoir tank that stores air, a compressor that operates based on an external input signal to compress the air, and an air suspension that operates based on air pressure. a first direction in the closed air circuit that is activated based on an external input signal to selectively communicate either the outlet side passage of the reservoir tank or the outlet side passage of the air suspension with the suction side passage of the compressor; a switching valve, which operates together with the first directional switching valve based on an external input signal to selectively transfer either the inlet side passage of the reservoir tank or the inlet side passage of the air suspension to the discharge side passage of the compressor; A second directional switching valve is interposed therebetween.

Function When the air suspension is activated to raise the vehicle height, when an up signal is input as an external input signal, the first directional control valve connects the outlet side passage of the reservoir tank and the suction side passage of the compressor. The second directional switching valve communicates the discharge side passage of the compressor with the inlet side passage of the air suspension, and the compressor operates to supply air from the reservoir tank to the air suspension. On the other hand, when lowering the vehicle height by operating the air suspension, if a down signal is input as an external input signal, the first directional control valve connects the air suspension outlet passage with the compressor suction passage. The second directional switching valve communicates the discharge side passage of the compressor with the inlet side passage of the reservoir tank, and the compressor operates to recirculate air from the air suspension to the reservoir tank.

Embodiments Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a first embodiment of the present invention.
is a reservoir tank that stores air. 2 is a compressor that operates based on an external input signal to compress air. Reference numeral 3 denotes an air suspension operated by air pressure, and the air suspension 3 constitutes a closed air circuit together with the reservoir tank 1 and the compressor 2. 4 is a first directional switching valve that switches the flow path in two directions based on an external input signal, and the inlet side of this first directional switching valve 4 has an outlet side passage 5 of the reservoir tank 1 and an outlet of the air suspension 3 The side passages 6 are connected to each other, and the suction side passage 7 of the compressor 2 is connected to the outlet side of the first directional control valve 4.
8 is a second directional switching valve that switches the flow path in two directions based on an external input signal, similar to the first directional switching valve 4; The outlet side of the second directional switching valve 8 is connected to an inlet side passage 10 of the reservoir tank 1 and an inlet side passage 11 of the air suspension 3, respectively. Reference numeral 12 denotes a bypass passage connected across the suction side passage 7 and the discharge side passage 9 of the compressor 2, and a one-way valve 13 is interposed in the middle of this bypass passage 12. When the pressure in the suction side passage 7 of the compressor 2 is higher than the pressure in the discharge side passage 9, this one-way valve 13 is operated from the outlet side of the first directional switching valve 4 to the inlet side of the second directional switching valve 8. This is to allow air to flow quickly. A pressure switch 14 detects the pressure inside the reservoir tank 1 and stops the operation of the compressor 2 when the pressure inside the reservoir tank 1 falls outside a predetermined pressure range. Reference numeral 15 denotes an air supply passage that communicates the inside and outside of the reservoir tank 1, and a one-way valve 16 is interposed in the middle of this air supply passage 15. This one-way valve 16 is designed to allow air to be introduced into the reservoir tank 1 from the outside in the event that air in the closed air circuit leaks to the outside.

In this embodiment configured as described above, when the air suspension 3 is activated to raise the vehicle height, when an up signal is input as an external input signal, the first directional control valve 4 is activated as shown in FIG. The outlet side passage 5 of the reservoir tank 1 and the suction side passage 7 of the compressor 2 communicate with each other, and the second directional switching valve 8 communicates the discharge side passage 9 of the compressor 2 with the inlet side passage 11 of the air suspension 3. , compressor 2 operates. At this time, the inlet side passage 10 of the reservoir tank 1 is closed by the second directional switching valve 8, and the outlet side passage 6 of the air suspension 3 is closed by the first directional switching valve 4.
Therefore, the air in the reservoir tank 1 is compressed by the compressor 2 and transferred to the air suspension 3.
is supplied to operate the air suspension 3. On the other hand, when lowering the vehicle height by operating the air suspension 3, if a down signal is input as an external input signal, the first directional control valve 4 moves to the left in the figure and moves toward the outlet side of the air suspension 3. The passage 6 and the suction side passage 7 of the compressor 2 are communicated, and the second directional switching valve 8 moves to the left in the figure to communicate the discharge side passage 9 of the compressor 2 and the inlet side passage 10 of the reservoir tank 1. At the same time, the compressor 2 is activated. At this time, the outlet side passage 5 of the reservoir tank 1 and the inlet side passage 11 of the air suspension 3 are closed. Therefore, the air in the air suspension 3 is compressed by the compressor 2 and returned to the reservoir tank 1. Note that when the pressure in the suction side passage 7 of the compressor 2 is higher than the pressure in the discharge side passage 9, the air in the reservoir tank 1 or the air suspension 3 is not only compressed by the compressor 2 but also
It passes through the bypass passage 12 and the one-way valve 13 and is supplied to the air suspension 3 or the reservoir tank 1.

FIG. 2 shows a second embodiment of the present invention, which will be described in detail without redundant explanations of the first embodiment.

That is, in this embodiment, the differential pressure detection switch 17
Reservoir tank 1 and air suspension 3
It detects the differential pressure between the reservoir tank 1 and the air suspension 3, and inputs an up signal as an external input signal while the pressure in the reservoir tank 1 is higher than the pressure in the air suspension 3. Even if the compressor 2 is not activated,
While the pressure of the air suspension 3 is higher than the pressure of the reservoir tank 1, the compressor 2 is not operated even if a down signal is input as an external input signal.

In this embodiment configured as described above, when the air suspension 3 is operated to raise the vehicle height, when the up signal is input as an external input signal, the second
As shown in the figure, the first directional switching valve 4 communicates the outlet side passage 5 of the reservoir tank 1 with the suction side passage 7 of the compressor 2, and the second directional switching valve 8 connects the outlet side passage 9 of the compressor 2 with the air suspension. The inlet side passages 11 of No. 3 are communicated with each other. The inlet passage 10 of the reservoir tank 1 is closed by the second directional valve 8, and the outlet passage 6 of the air suspension 3 is closed by the first directional valve 4.
At this time, while the pressure in the reservoir tank 1 is higher than the pressure in the air suspension 3, the compressor 2 does not operate even if the up signal is input because the differential pressure detection switch 17 is activated. Therefore, the air in the reservoir tank 1 is supplied to the air suspension 3 via the bypass passage 12 and the one-way valve 13 due to the pressure difference between the reservoir tank 1 and the air suspension 3. Activate. On the other hand, when lowering the vehicle height by operating the air suspension 3, if a down signal is input as an external input signal, the first directional control valve 4 moves to the left in the figure and moves toward the outlet side of the air suspension 3. The passage 6 and the suction side passage 7 of the compressor 2 are communicated, and the second directional switching valve 8 moves to the left in the figure to communicate the discharge side passage 9 of the compressor 2 and the inlet side passage 10 of the reservoir tank 1. . And reservoir tank 1
The outlet side passage 5 of the air suspension 3 is closed by the first directional control valve 4, and the inlet side passage 1 of the air suspension 3 is closed by the first directional control valve 4.
1 is closed by the second directional valve 8. At this time, while the pressure of the air suspension 3 is higher than the pressure of the reservoir tank 1, even if a down signal is input, the differential pressure detection switch 17 is activated, so the compressor 2 does not operate. Therefore, the air in the air suspension 3 is returned to the reservoir tank 1 via the bypass passage 12 and the one-way valve 13 due to the differential pressure between the air suspension 3 and the reservoir tank 1. In this way, according to this embodiment, the compressor 2 is not operated while there is a differential pressure between the reservoir tank 1 and the air suspension, so the power required to operate the compressor 2 can be saved. can.

FIG. 3 shows a third embodiment of the present invention, which will be described in detail without redundant explanations of the first embodiment.

That is, in this embodiment, a pressure switch 14a is provided in the reservoir tank 1, which is turned on when the pressure in the reservoir tank 1 becomes below a predetermined minimum pressure, and is turned off when the pressure in the reservoir tank 1 reaches a predetermined pressure set higher than the predetermined minimum pressure. A third directional switching valve 18 operated based on a pressure switch is interposed in the middle of the outlet side passage 5 of the reservoir tank 1 that connects the reservoir tank 1 and the first directional switching valve 4. . This third directional switching valve 18 normally connects the reservoir tank 1 and the first directional switching valve 4 to outlet side passages 5a and 5b of the reservoir tank 1.
are communicating. Reference numeral 19 denotes an air supply passage whose one end is connected to the inlet side of the third directional switching valve 18 and the other end is connected to the atmospheric air intake port 20. 8a communicates the discharge side passage 9 of the compressor 2 with the inlet side passage 10 of the reservoir tank 1 while the pressure switch 14a is turned on even if an up signal is input as an external input signal. The second
It is a directional valve.

In this embodiment configured as described above, when the air suspension 3 is activated to raise the vehicle height, if the pressure inside the reservoir tank 1 is higher than a predetermined minimum pressure, an up signal is input as an external input signal. As shown in FIG. 3, the third directional switching valve 18 communicates the outlet side passages 5a and 5b of the reservoir tank 1, and the first directional switching valve 4 communicates the outlet side passage 5 of the reservoir tank 1 with the suction side passage of the compressor 2. 7, and the second directional control valve 8a communicates with the compressor 2.
The discharge side passage 9 of the air suspension 3 and the inlet side passage 11 of the air suspension 3 are communicated with each other, and the compressor 2 is operated. At this time, the inlet side passage 10 of the reservoir tank 1 is closed by the second directional switching valve 8a, and the outlet side passage 6 of the air suspension 3 is closed.
is closed by the first directional valve 4. Therefore, the air in the reservoir tank 1 is compressed by the compressor 2 and supplied to the air suspension 3, thereby operating the air suspension 3. When the pressure inside the reservoir tank 1 becomes lower than a predetermined pressure, the pressure switch 14a is turned on, and the third directional control valve 18 moves to the left in the figure based on the on signal from the pressure switch 14a. The air supply passage 19 and the outlet side passage 5b of the reservoir tank 1 are communicated with each other, and external air is compressed by the compressor 2 and supplied to the reservoir tank 1. As a result, when the pressure inside the reservoir tank 1 is increased to a predetermined pressure, the pressure switch 14a is turned off, and based on the off signal from the pressure switch 14a, the third directional control valve 18 is returned to its original state. After returning to the state (right position in the figure), the outlet side passages 5a, 5 of the reservoir tank 1
At the same time, the second directional switching valve 8a returns to its original state (right side position in the figure), and the discharge side passage 9 of the compressor 2 and the inlet side passage 11 of the air suspension 3 are communicated with each other. Therefore, air is supplied to the air suspension 3 again, and the air suspension 3 continues to operate. As described above, according to this embodiment, the pressure inside the reservoir tank 1 can be maintained within a predetermined pressure range, and the compression ratio of the compressor 2 can be prevented from becoming abnormally large.
The discharge from the compressor 2 becomes easier. Furthermore, since the compression ratio of the compressor 2 can be made significantly smaller than in the above embodiments, it is possible to use an inexpensive compressor such as a diaphragm type compressor.

Note that when the air suspension 3 is operated to lower the vehicle height, if a down signal is input as an external input signal, the first directional control valve 4 and the second directional control valve 4 are activated as in the first embodiment. The valve 8a is activated to circulate the air in the air suspension 3 into the reservoir tank 1.

Effects of the Invention As described above, the present invention forms a closed air circuit using a reservoir tank that stores air, a compressor that operates based on an external input signal to compress the air, and an air suspension that operates based on the pressure of the air. the closed air circuit is actuated based on an external input signal to selectively communicate either the outlet side passage of the reservoir tank or the outlet side passage of the air suspension with the suction side passage of the compressor. a first directional switching valve that operates together with the first directional switching valve based on an external input signal to direct either the inlet side passage of the reservoir tank or the inlet side passage of the air suspension to the discharge side of the compressor. Since a second directional switching valve that selectively communicates with the passage is installed, there is no need for a low-pressure tank and a high-pressure tank as in the conventional example, and only one reservoir tank is required.
The entire air suspension device can be made small and
It has great practical effects in that it can be made at low cost and can be easily installed in small automobiles.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing a first embodiment of the present invention, FIG. 2 is a circuit diagram showing a second embodiment, and FIG. 3 is a circuit diagram showing a third embodiment. 1... Reservoir tank, 2... Compressor, 3... Air suspension, 4... First directional control valve, 5, 6... Outlet side passage, 7... Suction side passage, 8, 8a... Second Directional switching valve, 9...discharge side passage, 10, 11...inlet side passage.

Claims (1)

[Claims] 1. A closed air circuit is composed of a reservoir tank that stores air, a compressor that operates based on an external input signal to compress air, and an air suspension that operates based on air pressure. a first directional switching valve that is operated based on a signal to selectively communicate either the outlet side passage of the reservoir tank or the outlet side passage of the air suspension with the suction side passage of the compressor; a second directional switch which operates together with a directional control valve based on an external input signal to selectively communicate either the inlet side passage of the reservoir tank or the inlet side passage of the air suspension with the discharge side passage of the compressor; An air suspension device for automobiles equipped with a valve.