JPH04203541A - High voltage generator - Google Patents

Abstract

PURPOSE:To suppress the variation of the output voltage based on the variation of the resistance value of an external load by inserting a high resistance to the output side of a high voltage generator so as to be connected in parallel to the electric viscous resistance. CONSTITUTION:When the resistance value of the electric viscous fluid varies according to the temperature variation, etc., the conventional device in which only an external load 20 is connected with an output terminal 9a receives the variation of the resistance value as it is, and the voltage value of the dc high voltage generated at the output terminal 9a varies drastically. While, as for the device in which a high resistance 10 is connected in parallel with the output terminal 9a, together with the external load 20, the output electric current is shunted also to the high resistance 10, and the variation of the electric current value led out from the output terminal 9a reduces, and the voltage value of the dc high voltage generated at the output terminal 9a is stabilized. In this case, as the high resistance 10, is preferably used the resistance having the resistance value in about two-ten times of the resistance value of the external load 20 at the normal temperature.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a controlled engine mount device filled with a variable viscosity fluid that reduces engine vibration and noise, and in particular, the present invention relates to a controlled engine mount device filled with a variable viscosity fluid that reduces engine vibration and noise. The present invention relates to a high voltage generator for supplying high voltage.

[Prior art] Conventionally, a variable viscosity fluid is sealed in an engine mount device,
As a means for adjusting the viscosity of the variable viscosity fluid by supplying a high voltage to the variable viscosity fluid and reducing the vibration and noise generated by the engine, there is a method disclosed in Japanese Patent Application Laid-Open No. 2-3518.
No., JP-A-1-193427, JP-A-1-3'122
There were devices described in No. 41 and Japanese Patent Application Laid-Open No. 64-46036. In these inventions, although the structure of the engine mount device is specifically shown, nothing is shown about the structure of the high voltage generator that supplies high voltage to the variable viscosity fluid.

[Problems to be Solved by the Invention] All of the conventional devices described above use a high voltage generator for supplying a DC high voltage to a variable viscosity fluid, but the variable viscosity fluid, which constitutes an external load, High voltage is generated in response to changes in resistance due to changes in fluid temperature (for example, in the case of certain viscosity variable fluids, the resistance at 80°C is 1/3 of the resistance at room temperature). Since no consideration has been given to reducing fluctuations in the output voltage of the device, there has been a problem in that the output voltage of the high voltage generator fluctuates significantly due to fluctuations in the resistance value of the external load.

Furthermore, although it is known that a large-capacity high-voltage generator is used to stabilize the output voltage against fluctuations in the resistance value of an external load, if a large-capacity high-voltage generator is constructed, There were also problems in that the manufacturing cost and volume increased.

The present invention was devised to eliminate such problems, and one purpose is to provide a high voltage generator that suppresses fluctuations in output voltage due to fluctuations in the resistance value of an external load. It is about providing.

Another object of the present invention is to provide a high voltage generator that detects high voltage leagues occurring in or around an external load, or that reduces heat generation of the external load.

[Problems for Solving the Problems] In order to achieve the above-mentioned one object, the present invention provides a resistor (with high withstand voltage and high resistance value) for the external load (electrorheological fluid) on the output side of the high voltage generator. (hereinafter referred to as high resistance) are connected in parallel.

To achieve the objective of the above values, the present invention detects the current output flowing through a high resistance connected in parallel or the voltage output of a detection resistor connected in series thereto, and by means of these outputs the current supply of the high voltage generator is determined. I'm trying to control the movement.

[Action: External load (electrorheological resistance) is applied to the output side of the high voltage generator.
If a high resistance is connected in parallel to the high resistance, the output DC current of the high voltage generator will flow to both the external load and the high resistance, so even if the resistance value of the external load changes due to temperature changes, there will be no shunt effect to the high resistance. This reduces changes (variations) in the current flowing to the external load. In addition, if the current value that is shunted to the high resistance is detected by means such as connecting a detection resistor in series with the high resistance, high voltage leakage that occurs in the external load and its surroundings can be detected based on large fluctuations in the detected value. can be detected. Further, by controlling the output DC voltage of the high voltage generator based on the shunted current value, the output voltage of the high voltage generator, heat generation of the external load, etc. can be controlled.

[Example code] Embodiments of the present invention will be described using the drawings.

FIG. 1 is a block diagram schematically showing an engine mount control system.

In the figure, 1 is an automobile engine, 2 is an engine mount in which an electrorheological fluid is sealed, 3 is a high voltage generator according to the present invention, and 4 is a control unit.

Then, the control unit 4 supplies a signal according to the control state to the high voltage generator 3. The high voltage generator 3 supplies an output DC current to the engine mount 2 in response to the supplied signal. This controls the viscosity of the electrorheological fluid sealed in the engine mount.

FIG. 2 is a circuit diagram showing one embodiment of the high voltage generator according to the present invention.

In the figure, 5 is an oscillation circuit, 6 is an amplifier circuit, 7 is a switching transistor, 8 is a step-up transformer, 9 is a rectifier circuit, 9a is an output terminal, 10 is a high resistance, 11 is a detection resistor, 1
2.13 is a reference voltage setting resistor, 14 is a comparison circuit, 15.
16 is a control switching transistor, 17 is an input resistor, 17a is a control signal input terminal, 18 and 19 are resistors and Zener diodes for stabilizing DC voltage, and 20 is an external load.

A high frequency pulse signal periodically generated in the oscillation circuit 5 is amplified by an amplifier 6 and then supplied to a switching transistor 7 to turn it on and off. The switching signal generated by turning on and off the transistor 7 is boosted in the step-up transformer 8, and generates a high voltage switching signal on its secondary side. Next, this high voltage switching signal is rectified by the rectifier circuit 9, converted into a DC high voltage, and supplied to the output terminal 9a. In addition to the external load 20, the output terminal 9a is also connected to a high resistance 10.
are connected in parallel, and the output current derived from the output terminal 9a is divided into an external load 20 and a high resistance 10.

Here, when the resistance value of the electrorheological fluid changes based on a temperature change or the like, the conventional device in which only the external load 20 is connected to the output terminal 9a receives the change in resistance value as it is, and the output terminal 9a While the voltage value of the DC high voltage generated at the output terminal 9 fluctuates significantly,
In the device of this embodiment in which a high resistance 10 is connected in parallel to an external load 20, the output current is also shunted to the high resistance 10, so changes in the current value derived from the output terminal 9a can be reduced. As a result, the voltage value of the DC high voltage generated at the output terminal 9a can be stabilized.

In this case, the high resistance 10 has a resistance value approximately 2 to 10 times the resistance value of the external load 20 at room temperature (
That is, the current value of the external load 20 is 1 force Y, τ0°5 to 0.
It is preferable to use one that allows 1 times as much current to flow.

Further, a detection resistor 11 is connected in series to the high resistance 10, and the current shunted to the high resistance 10 also flows to the detection resistor 11, and the terminal voltage Vr obtained across the detection resistor 11 is output to the comparator 14. Inverting input 14 b i,'1 is supplied. In addition, the reference voltage Vs set by the reference voltage setting @ resistor 12.13 is supplied to the non-inverting inputs 1 and 1a of the comparator 14, and the terminal voltage Vr and the reference voltage Vs are compared in the comparator 14. be done.

Between the two voltages Vr and Vs, normally Vr)V
s, and the output signal of the comparator 8 is at a low level. However, when a high voltage leak occurs in the external load 20 or its surroundings, the current flowing through the high resistance 10 and the detection resistance 11 suddenly decreases, so the above relationship is reversed and the voltage becomes Vr (Vs). The output signal of the comparator 8 is converted to a high level. This high/bell output is supplied to the control switching transistor 15 to turn it on, and the output high frequency pulse signal of the oscillation circuit 5 is passed through the transistor 15. Since the circuit is bypassed to the ground point, the switching transistor 7 becomes inactive, and the output high voltage is no longer sent to the output terminal 9a, thereby protecting the device from high voltage leaks occurring in the external load 20 and its surroundings. can do.

Note that in the above operation, the transmission of the output high voltage is stopped by detecting the current flowing through the high resistance 10, but a control pulse is supplied to the control signal terminal 17a, thereby controlling the control switching. Even if the transistor 16 is turned on, the transmission of the output high voltage can be stopped through a similar operation process.

Furthermore, in this embodiment, a plurality of resistors each having a different resistance value are connected in parallel or in series as the high resistor 10, and the resistors are By selecting one having a predetermined resistance value among them, it is possible to control the DC high voltage at the output terminal 9a to be approximately constant.

In the above-mentioned example, a plurality of resistors each having a high resistance (0) and different resistance values are connected in parallel or in series. A plurality of taps are provided on the next side or the secondary side, and a predetermined one of these taps is selected depending on the magnitude of the terminal voltage detected by the detection resistor 11.
J, where the DC high voltage at the output terminal 9a becomes almost constant even when
can be controlled.

If these controls are performed, for example, when the electrorheological fluid generates a large amount of heat, it is possible to limit the current value flowing through the electrorheological fluid and suppress the heat generation.

FIG. 3 is a structural diagram showing an example of an actual usage of the high voltage generating circuit of the present invention, in which the high voltage generating circuit is formed by molding.

In the figure, 21.21 is a plurality of output terminals, 22.22
are a plurality of input connectors; 23 is a mold body; the plurality of input connectors 22 are at least made up of a control terminal, a power supply terminal, and a ground terminal; in this example, a plurality of output terminals are connected from the mold body 23; 22 is derived, but
By adopting such a configuration, by designing the output power capacity of the high voltage generation circuit with a margin, it is possible to supply DC high voltage to the engine mount control system from one output terminal 22, and at the same time, Other pressure terminal 2
2 can also power other on-vehicle devices that require DC voltage.

[Effects of the Invention] As described above, in the present invention, a high resistance is connected in parallel to an external load at the output section of a high voltage generation circuit, so that fluctuations in the resistance value of the external load occur due to temperature changes, etc. Also, fluctuations in the output DC voltage value of the high voltage generation circuit can be suppressed.

In addition, by detecting the current flowing through high resistances connected in parallel, it is possible to detect high voltage leaks that occur in the high voltage generation circuit and its surroundings, and furthermore, the output DC voltage is controlled to reduce heat generation in external loads. It will also be possible to do so.

[Brief explanation of the drawing]

Figure 1 is a configuration diagram of the engine mount control system, Figure 2
The figure is a configuration circuit diagram of a high voltage generator according to the present invention, and FIG. 3 is a structural diagram when the high voltage generator is molded. 1... Engine, 2... Engine mount, 3... High voltage generation circuit, 4...
... Control unit, 5... ... Oscillator circuit, 6... ... Amplifier circuit, 7... ... Switching transistor, 8... ... Step-up transformer, 9.
... Rectifier circuit, 9a... Output terminal,
10... High resistance, 11... Detection resistor, 12.13... Reference voltage setting resistor 14
... Comparison circuit, 15.16... Control switching transistor, 17... Input resistor, 17a... Control signal terminal, 18.19
...Resistance for generating reference voltage and Zener diode, 20... ...External load, 21...
...Output terminal, 22... ...Input connector, 23
...Mold body. Fig. 1 Fig. 2 j'''14' comparison 83 (a) (b)

Claims (1)

[Scope of Claims] 1. In an engine mount control system using an electrorheological fluid whose resin viscosity changes due to the application of a high DC voltage from a high voltage generator to a vibration absorbing mount part of the engine, the electrorheological resistance An engine mount control system characterized by inserting a high resistance on the output side of a high voltage generator so that it is connected in parallel to the output side of the high voltage generator. 2. An engine mount control system comprising means for detecting the current flowing through the high resistance according to claim 1. 3. An engine mount control system that detects the current flowing through the high resistance according to claim 1 and controls the output voltage of the high voltage generator according to the detection result.