JP4475232B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device, and more particularly to an electronic device having a plurality of internal power supplies.

  Generally, electronic devices that operate by receiving power supply from the outside are provided with noise countermeasures for preventing noise received from the outside. As a means for preventing noise flowing in from an external power supply line, there is a noise filter including a choke coil, a capacitor, a Zener diode, and the like in the vicinity of a power input portion connected to an external power supply (see, for example, Patent Document 1).

Moreover, there is a controller having a plurality of (for example, two) internal power supplies as an electronic device. As shown in FIG. 2, the controller 41 includes a first internal power supply 42 and a second internal power supply 43. The first internal power supply 42 and the second internal power supply 43 include dedicated noise filters 44 and 45, respectively. The noise filters 44 and 45 include choke coils 44a and 45a, capacitors 44b, 44d, 45b and 45d, and Zener diodes 44c and 45c, respectively. The first internal power supply 42 is supplied with power through the external switch 47 and the noise filter 44 in a state where the controller 41 is connected to the external power supply 46. In order to reduce power consumption in the standby state, power is not supplied from the external power supply 46 when the external switch 47 is not in the ON state. The second internal power supply 43 is always supplied with power from the external power supply 46 via the noise filter 45 and the three-terminal regulator 48 without passing through the external switch 47.
JP-A-2005-216906

  In the controller 41 having the two internal power sources, noise filters 44 and 45 are provided in the first internal power source 42 and the second internal power source 43, respectively. Since the noise filter has a large element size, in the configuration provided with the noise filter for each internal power supply, a substrate having a large area is required to configure the controller, and the controller is also enlarged.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an internal power source to which external power is constantly supplied and an internal power source to which external power is supplied when the external switch is in an ON state. An object of the present invention is to provide an electronic device that can be reduced in size by reducing the number of components mounted on a substrate constituting the electronic device and reducing the area of the substrate.

  In order to achieve the above object, an invention according to claim 1 is an electronic device used by being connected to an external power source. Further, a noise filter for preventing noise flowing in from the external power supply, and ON / OFF corresponding to ON / OFF of the external switch connected to the external power supply in a state where an electronic device is connected to the external power supply And a semiconductor switch capable of supplying the external power via the noise filter. In addition, at least one first internal power source to which the external power source is supplied via the semiconductor switch, and power is always supplied from the external power source via the noise filter in a state where an electronic device is connected to the external power source. And at least one second internal power source.

  In the present invention, in the state where the electronic device is connected to the external power supply, the external power supply is supplied through the semiconductor switch that is switched ON / OFF in response to the ON / OFF of the external switch connected to the external power supply. A noise filter is shared by one internal power supply and a second internal power supply that is always supplied with power from an external power supply. Therefore, unlike a conventional electronic device, even if the first internal power supply and the second internal power supply are provided, there is no need to provide a noise filter for each of the first internal power supply and the second internal power supply. The number of components to be mounted on a necessary board can be reduced, the area of the board can be reduced, and the electronic apparatus can be miniaturized.

In the invention according to claim 1, the electronic device is a controller including a microcomputer, and the semiconductor switch is always supplied with power from an external power source when the electronic device is connected to the external power source. ON / OFF control is performed by the microcomputer. In the present invention, the microcomputer monitors the ON / OFF state of the external switch, and controls the ON / OFF of the semiconductor switch in response to the ON / OFF state of the external switch. Therefore, it can be easily configured by adding some functions to the microcomputer originally provided in the electronic apparatus.

According to a second aspect of the present invention, in the first aspect of the present invention, the semiconductor switch is a MOSFET. In the present invention, since the semiconductor switch is constituted by a MOSFET, the semiconductor switch has a good ON / OFF response and can be easily produced as compared with the case where it is constituted by another transistor such as a bipolar transistor.

  According to the present invention, in an electronic device including an internal power source to which external power is constantly supplied and an internal power source to which external power is supplied when the external switch is in an ON state, the area of the substrate constituting the electronic device is reduced. The electronic device can be reduced in size by being narrowed.

  Hereinafter, an embodiment in which the present invention is embodied in an in-vehicle controller as an electronic device, for example, a controller for a VSCS (Vehicle Speed Control System) capable of limiting the maximum vehicle speed at an arbitrary speed, will be described with reference to FIG. explain.

  As shown in FIG. 1, the controller 11 includes a first internal power supply 12 and a second internal power supply 13, and prevents noise flowing from the external power supply 14 when the controller 11 is connected to the external power supply 14. A noise filter 15 is provided.

  The controller 11 includes two plus input terminals 16a and 16b and one minus input terminal 16c. Since the noise filter 15 is shared by the first internal power supply 12 and the second internal power supply 13, it is connected between one plus input terminal 16 a and minus input terminal 16 c of the controller 11. The noise filter 15 includes a Zener diode 17, a choke coil 18, and capacitors 19 and 24. The Zener diode 17 has a cathode connected to the positive input terminal 16a side and an anode connected to the negative input terminal 16c side. The negative input terminal 16c is grounded.

  The other plus input terminal 16 b is connected to the plus terminal 14 a of the external power supply 14 via the external switch 20. Specifically, the external switch 20 is, for example, an ignition key switch. In the controller 11, there is provided a semiconductor switch 21 configured to be switched ON / OFF corresponding to ON / OFF of the external switch 20. The first internal power supply 12 is connected to the external power supply 14 via the noise filter 15 and the semiconductor switch 21, and is externally connected via the external switch 20, the noise filter 15, and the semiconductor switch 21 in the ON state of the external switch 20 and the semiconductor switch 21. A power supply 14 is supplied.

  In this embodiment, a MOSFET is used as the semiconductor switch 21, and the MOSFET is controlled to be turned ON / OFF by a microcomputer 22 that is always supplied with power from the external power supply 14 in a state where the controller 11 is connected to the external power supply 14. Is done. The microcomputer 22 is connected to the second internal power supply 13 that is always supplied with power from the external power supply 14 in a state where the controller 11 is connected to the external power supply 14.

  In addition to the microcomputer 22, monitoring electronic components are connected to the second internal power supply 13. The microcomputer 22 monitors the ON / OFF state of the external switch 20, and when the external switch 20 is turned ON, the semiconductor switch 21 is turned ON, and when the external switch 20 is turned OFF, the semiconductor switch 21 is turned OFF. The semiconductor switch 21 is controlled.

  The microcomputer 22 indirectly controls the throttle lever by control of a motor or the like based on the opening degree of the accelerator pedal operated by the operator and vehicle speed information.

  The drain of the MOSFET constituting the semiconductor switch 21 is connected to the output part of the noise filter 15, and the source of the MOSFET is connected to the input terminal of the first internal power supply 12. A control signal is output to the gate of the MOSFET via a drive circuit (not shown) based on the control signal from the microcomputer 22.

  The second internal power supply 13 is connected to the output terminal 25 b of the three-terminal regulator 25. The three-terminal regulator 25 has an input terminal 25a connected to the output part of the noise filter 15, and a ground terminal 25c connected to the negative input terminal 16c. A diode 26 is connected between the input terminal 25a and the output terminal 25b of the three-terminal regulator 25 with the cathode connected to the input terminal 25a. Capacitors 27 and 28 are connected in parallel to the input side and output side of the three-terminal regulator 25, and an electrolytic capacitor 29 is connected in parallel to the capacitor 28. A Zener diode 30 is connected in parallel with the electrolytic capacitor 29.

Next, the operation of the controller 11 configured as described above will be described.
The controller 11 has a positive input terminal 16 a connected to the positive terminal 14 a of the external power supply 14, a positive input terminal 16 b connected to the positive terminal 14 a of the external power supply 14 via the external switch 20, and a negative input terminal 16 c connected to the external power supply 14. It is used in a state where it is connected to the negative terminal 14b.

  When the controller 11 is connected to the external power supply 14, the second internal power supply 13 is always supplied with power via the noise filter 15 and the three-terminal regulator 25. Since power is supplied through the noise filter 15, the inflow of high frequency noise from the external power supply 14 is blocked by the action of the choke coil 18 and the capacitors 19 and 24. Further, when an overvoltage is supplied from the external power supply 14, a voltage equal to or lower than the set voltage of the Zener diode 17 is supplied to the downstream side of the connection point of the Zener diode 17 due to the action of the Zener diode 17. In addition, when an inrush current flows from the external power supply 14, the inrush current is suppressed from flowing downstream by the action of the choke coil 18.

  In the standby state of the controller 11, that is, when the external switch 20 is OFF, power is supplied from the external power supply 14 only to the second internal power supply 13. The second internal power supply 13 is connected only to the electronic components and the microcomputer 22 that are necessary so that the controller 11 can be immediately put into use when the external switch 20 is turned on. The power consumption in the standby state can be suppressed.

  When the external switch 20 is turned on, the microcomputer 22 outputs a command signal for turning on the semiconductor switch 21, the semiconductor switch 21 is turned on, and power is supplied from the external power supply 14 to the first internal power supply 12. Supplied. The power is stabilized by a three-terminal regulator 25 and supplied to a predetermined voltage. Then, each operation unit is controlled by a command from the microcomputer 22.

This embodiment has the following effects.
(1) When the controller 11 is connected to the external power source 14, the external power source 14 is connected via the semiconductor switch 21 that is switched ON / OFF in response to the ON / OFF of the external switch 20 connected to the external power source 14. The noise filter 15 is shared by the first internal power supply 12 that is supplied and the second internal power supply 13 that is always supplied with power from the external power supply 14. Therefore, unlike the conventional controller, even if the first internal power supply 12 and the second internal power supply 13 are provided, it is not necessary to provide the noise filter 15 for each of the first internal power supply 12 and the second internal power supply 13. The area of the substrate necessary for mounting the controller 11 can be reduced, and the controller 11 can be reduced in size.

  (2) The semiconductor switch 21 is controlled to be turned ON / OFF by the microcomputer 22 to which power is always supplied from the external power supply 14 in a state where the controller 11 is connected to the external power supply 14. Therefore, it can be easily configured by adding the ON / OFF control function of the semiconductor switch 21 to the microcomputer 22 originally provided in the controller 11.

  (3) Since the semiconductor switch 21 is constituted by a MOSFET, the semiconductor switch 21 has a better ON / OFF responsiveness than the case where it is constituted by another transistor such as a bipolar transistor, and can be easily produced.

(4) Although there is a strong demand for miniaturization of in-vehicle electronic devices, the demand for miniaturization can be answered by being embodied in the in-vehicle controller 11.
(5) When a forklift is equipped with a VSCS function for limiting the maximum vehicle speed at an arbitrary speed, the controller 11 can be reduced in size, so that the degree of freedom of installation space for the controller 11 is increased.

The embodiment is not limited to the above, and may be embodied as follows, for example.
The semiconductor switch 21 is not limited to a MOSFET, but may be another transistor, for example, a bipolar transistor, an electrostatic induction transistor, or an IGBT (Insuiated Gate Bipolar Transistor). However, MOSFETs are preferable because they have good responsiveness when the switch is turned on and off, and can be easily formed.

The semiconductor switch 21 is not limited to a transistor, and a semiconductor contactless relay such as an SSR (solid state relay) or an optical MOS relay may be used.
The semiconductor switch 21 is not limited to a configuration in which ON / OFF control is performed according to a command from the microcomputer 22, and may be configured to be directly switched ON / OFF in response to ON / OFF of the external switch 20. For example, when a MOSFET is used as the semiconductor switch 21, the drain is connected to the output part of the noise filter 15, the source is connected to the input terminal of the first internal power supply 12, and the gate is connected to the positive input terminal 16b.

  ○ The number of internal power supplies is not limited to two, but may be applied to electronic devices having three or more internal power supplies. That is, in an electronic device having a plurality of internal power supplies, at least one internal power supply is a first internal power supply that is supplied with power through a semiconductor switch that can be switched ON / OFF in conjunction with an external switch. The two internal power supplies may be applied to an electronic device that is the second internal power supply in a state where power is always supplied from the external power supply.

  ○ In-vehicle electronic devices are not limited to VSCS controllers in forklifts. For example, they can be applied to OPS (Operator Presence Sensing) controllers, which are systems that enhance safety when an operator leaves the driver's seat. May be.

○ The present invention is not limited to an on-vehicle electronic device, and may be applied to, for example, a control device for a stationary machine.
The following technical idea (invention) can be understood from the embodiment.
(1) before Symbol electronic devices is a controller for the vehicle.

(2) In the invention described in the technical idea (1), the controller is a controller that arbitrarily controls the maximum vehicle speed in the forklift.
(3) In the invention described in the technical idea (1), the controller is a controller that controls the operation of the operation unit in association with the leaving of the operator.

The circuit diagram of one embodiment. The circuit diagram of a prior art.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Controller as an electronic device, 12 ... 1st internal power supply, 13 ... 2nd internal power supply, 14 ... External power supply, 15 ... Noise filter, 20 ... External switch, 21 ... Semiconductor switch, 22 ... Microcomputer.

Claims (2)

An electronic device used by being connected to an external power source,
A noise filter for preventing noise flowing in from the external power source;
A semiconductor that can be turned ON / OFF in response to ON / OFF of an external switch connected to the external power supply in a state where an electronic device is connected to the external power supply and that can supply the external power supply via the noise filter A switch,
At least one first internal power source to which the external power source is supplied via the semiconductor switch;
Including at least one second internal power source to which power is always supplied from the external power source via the noise filter in a state where an electronic device is connected to the external power source ,
The electronic device is a controller including a microcomputer, and the semiconductor switch is controlled to be turned on and off by the microcomputer, which is always supplied with power from the external power source in a state where the electronic device is connected to the external power source. Electronics. The electronic device according to claim 1, wherein the semiconductor switch is a MOSFET .

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