JP2010188932A - Electric power steering device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simultaneously achieve a large current of a motor current for controlling an electric motor in order to increase a steering assist force, and a miniaturization of a control unit in order to improve on-vehicle mountability. <P>SOLUTION: Components 28a and 28b constituting a part of a driving circuit are mounted on a first metal substrate 23, and a component 30 constituting the rest of the driving circuit is mounted on a second metal substrate 24. The first metal substrate 23 is secured on a bottom plate 21c of a heat radiation case 21. The second metal substrate 24 is secured on a support plate 22b of an auxiliary heat radiation plate 22 integrated into the heat radiation case 21 so as to divide a part of space between the first metal substrate 23 and an insulating substrate 25 secured to cover an opening of the heat radiation case 21. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention controls a steering column having a steering shaft to which a steering torque is transmitted, an electric motor that transmits a steering assist force (assist force) to the steering shaft via a reduction mechanism in a reduction gear box, and the electric motor. The present invention relates to an electric power steering device including a control unit.

  As a control unit for the electric power steering apparatus, a drive circuit including a switching element connected to the power line of the electric motor, a control circuit for controlling the operation of the switching element, and a single metal made of a metal material on which the drive circuit is mounted A substrate, an insulating substrate made of an insulating material on which a control circuit is mounted, and a heat radiating case constituting the outer wall of the control unit are provided, and a metal substrate is attached in the heat radiating case so that a laminated state is formed on the metal substrate. Further, there is known a structure in which an insulating substrate is mounted in a heat dissipation case and a metal substrate and an insulating terminal are connected via a signal terminal and a power terminal (for example, Patent Document 1).

  Further, when the motor current of the electric motor is increased, the self-heating of the drive circuit components mounted on the metal substrate is increased and the thermal resistance cannot be obtained. Therefore, a technology is known in which a temperature sensor such as a thermistor is mounted on a metal substrate, and the self-heating of the drive circuit components mounted on the metal substrate is reduced by reducing the motor current when the temperature detected by the temperature sensor rises ( For example, Patent Document 2).

JP 2003-11829 A JP 2003-19973 A

By the way, when an electric power steering device is used for a large vehicle, it is necessary to simultaneously increase the motor current supplied to the electric motor in order to increase the assist force and to reduce the size of the control unit in order to improve the vehicle mountability. Has been.
The insulating substrate on which the control circuit of the control unit of Patent Document 1 is mounted can be reduced in size by reducing the number of control circuit components by increasing the functionality of the microcomputer, or by performing application specific IC (ASIC) or other semiconductor integrated circuits. It is. However, one metal substrate on which the drive circuit is mounted has a small area because the heat dissipation volume necessary for heat dissipation of the drive circuit component that self-heats with a large current must be secured even if the drive circuit component is downsized. It cannot be made into a small metal substrate.

Therefore, Patent Document 1 cannot achieve both a large motor current and a small control unit.
Here, two or more metal substrates are attached to the internal space of the heat radiating case, and a drive circuit component having large self-heating is divided and mounted on each metal substrate. Although it is conceivable to control the motor current based on the temperature detected by the temperature sensor, it is possible to suppress the self-heating of the drive circuit components, but multiple temperature sensors and circuits necessary for signal processing of these temperature sensors are required. Therefore, there is a problem in terms of cost increase due to an increase in the number of parts.

  Therefore, the present invention has been made paying attention to the unsolved problems of the above-described conventional example, increasing the motor current for controlling the electric motor in order to increase the steering assist force, and improving the vehicle mountability. Therefore, an object of the present invention is to provide an electric power steering device that can simultaneously reduce the size of a control unit.

  In order to achieve the above object, an electric power steering apparatus according to a first aspect of the present invention includes a steering column having a steering shaft to which steering torque is transmitted, and a steering assist to the steering shaft via a reduction mechanism in a reduction gear box. An electric power steering apparatus comprising: an electric motor that transmits force; and a control unit that controls the electric motor. The control unit is fixed to a heat radiating case having an opening and a bottom surface in the heat radiating case. A first metal substrate, a support plate overlapping a part of the first metal substrate with a predetermined space therebetween, and fixed to the heat radiating case, and fixed on the support plate Fixed to the opening side of the heat radiating case so as to cover the second metal substrate and the first metal substrate and the second metal substrate. An insulating substrate, a part of the first metal substrate that overlaps the support plate and a part of the drive circuit that is mounted on a portion of the first metal substrate that does not overlap the support plate, and the second metal substrate. The remaining components constituting the mounted drive circuit and the components constituting the control circuit and the power supply circuit mounted on the insulating substrate are provided.

  According to a second aspect of the present invention, there is provided the electric power steering apparatus according to the first aspect, wherein the drive circuit having a low height is provided on a portion of the first metal substrate overlapping the support plate and the second metal substrate. The components constituting the drive circuit having a high height are mounted on the portion of the first metal substrate that does not overlap the support plate.

According to a third aspect of the present invention, in the electric power steering apparatus according to the first or second aspect, the control unit is configured to overheat components constituting the drive circuit mounted on the first and second metal substrates. Overheat prevention function to prevent
According to a fourth aspect of the present invention, in the electric power steering apparatus according to the third aspect, the overheat prevention function is configured to control an ambient temperature of components constituting the drive circuit mounted on the first and second metal substrates. An ambient temperature detecting means for detecting; a junction temperature calculating means for calculating a junction temperature of a component constituting the drive circuit based on the ambient temperature detecting means; and the electric motor based on the junction temperature calculated by the junction temperature calculating means. Control current changing means for changing the control current of the motor.

  According to a fifth aspect of the present invention, in the electric power steering apparatus according to the fourth aspect, the ambient temperature detecting means is disposed on the first metal substrate close to the second metal substrate, and the junction The temperature calculation means sets the ambient temperature detected by the ambient temperature detection means as the first junction temperature of a part of the drive circuit mounted on the first metal substrate, and the ambient temperature detection means detects A second junction temperature of the remaining components constituting the drive circuit mounted on the second metal substrate is estimated based on the ambient temperature, and the control current changing means is configured to calculate the first junction temperature and the second junction temperature. The control current of the electric motor is changed based on the higher temperature.

  Further, the invention according to claim 6 is the electric power steering apparatus according to claim 5, wherein the junction temperature calculation means is the first junction based on a thermal resistance, a heat capacity, etc. of the components of the drive circuit stored in advance. The temperature and the second junction temperature are corrected.

According to the electric power steering apparatus according to the present invention, even when the motor current for controlling the electric motor 5 becomes a large current, the drive circuit is mounted on the first metal substrate 23 and the second metal substrate 24. Thus, a sufficient heat radiation area of the drive circuit that self-heats can be secured.
Moreover, since the components constituting the drive circuit are arranged so as to overlap each other, the control unit can be reduced in size and the vehicle mounting property can be improved.

  Therefore, the electric power steering apparatus according to the present invention has a control unit for increasing the motor current for controlling the electric motor in order to increase the steering assist force according to the steering torque of the steering wheel and for improving the vehicle mountability. Can be simultaneously reduced in size.

It is the perspective view shown from the right direction at the time of applying one Embodiment of the electric power steering device which concerns on this invention to a right-hand drive vehicle. It is a disassembled perspective view of a control unit. It is a longitudinal cross-sectional view which shows the principal part of a reduction gear box. It is a circuit block diagram of a control unit. It is principal part sectional drawing of a control unit. It is an overheat prevention functional block diagram concerning the present invention. It is a flowchart which shows an overheat prevention function. It is a flowchart which shows junction temperature calculation processing routine. It is a graph which shows the junction temperature calculation table memorize | stored beforehand. It is a graph which shows the temperature protection table memorize | stored beforehand.

Hereinafter, the best mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing an electric power steering apparatus according to an embodiment of the present invention applied to a right-hand drive vehicle from the right direction, FIG. 2 is an exploded perspective view of a control unit, and FIG. 4 is a circuit block diagram of the control unit, FIG. 5 is a cross-sectional view of the main part of the control unit, FIG. 6 is a block diagram of an overheat prevention function according to the present invention, and FIG. 7 shows an overheat prevention function. 8 is a flowchart showing a junction temperature calculation processing routine, FIG. 9 is a junction temperature calculation table stored in the control circuit, and FIG. 10 is a temperature protection table stored in the control circuit.

  In FIG. 1, reference numeral 1 denotes a column-type electric power steering device, in which a reduction gear box 4 is connected to a steering column 3 that rotatably houses a steering shaft 2 connected to a steering wheel (not shown). An electric motor 5 whose axial direction is extended in a direction perpendicular to the axial direction of the steering column 3 is disposed in the reduction gear box 4.

  The steering column 3 has a double tube structure of an inner tube 3a and an outer tube 3b. The outer tube 3 b and the reduction gear box 4 of the steering column 3 are attached to the vehicle body side by an upper mounting bracket 6 and a lower mounting bracket 7. The lower mounting bracket 7 is composed of a mounting plate portion 7a attached to a vehicle body side member (not shown) and a pair of support plate portions 7b extending in parallel from the lower surface of the mounting plate portion 7a with a predetermined distance in the left-right direction. Is formed. And the lower end of the support plate part 7b is rotatably connected to the support part 4b integrally formed in the vehicle front side of the reduction gear box 4 via the pivot 7c.

  The upper mounting bracket 6 includes a mounting plate portion 6a attached to a vehicle body side member (not shown) and a pair of support plate portions fixed to the lower end of the mounting plate portion 6a and spaced apart in the left-right (vehicle width) direction. 6b and a tilt mechanism 6c for supporting the outer tube 3b of the steering column 3 formed on the pair of support plate portions 6b. Then, the tilt lever 6g of the tilt mechanism 6c is rotated to release the support state of the outer tube 3b, whereby the tilt position of the steering column 3 can be adjusted up and down around the pivot 7c of the lower mounting bracket 7. .

As shown in FIG. 3, the steering shaft 2 includes an input shaft 2a whose upper end is connected to a steering wheel (not shown), and a torsion bar 2b connected to the lower end of the input shaft 2a via a torsion bar 2b. It is comprised with the output shaft 2c to cover.
The reduction gear box 4 is formed by die-casting, for example, any one of materials having high thermal conductivity, such as aluminum, aluminum alloy, magnesium, and magnesium alloy.

  The reduction gear box 4 has a worm storage part 12 for storing a worm 11 connected to an output shaft (not shown) of the electric motor 5, and a central axis orthogonal to the central axis below the worm storage part 12. A worm wheel storage portion 14 for storing a worm wheel 13 that meshes with the worm 11 and a torque sensor storage portion 16 for storing a torque sensor 15 that is integrally and coaxially connected to the vehicle rear side of the worm wheel storage portion 14. A motor mounting portion 17 for mounting the electric motor 5 formed on the open end surface of the worm storage portion 12, a cylindrical column mounting portion 18 formed at the rear end of the vehicle of the torque sensor storage portion 16, and the worm storage portion 12 And a control unit mounting portion 20 for mounting a control unit 19 formed over a part of the worm wheel storage portion 14. The vehicle front end portion of the steering column 3 is externally fitted and connected to the column mounting portion 18 of the reduction gear box 4.

  The torque sensor 15 is configured to magnetically detect a twisted state between the input shaft 2a and the output shaft 2c of the steering shaft 2 and detect a steering torque transmitted to the steering shaft with a pair of detection coils. The external connection terminals 15c, 15d and 15e, 15f projecting outside in parallel to the direction orthogonal to the central axis of the steering column 3 are connected to the start and end of the detection coil of the detection coil. The projecting portion is bent at the central portion in parallel with the central axis of the steering column 3, and is formed in an L shape.

As shown in FIG. 2, the electric motor 5 has connection terminals 5c and 5d formed at positions close to and opposed to the control unit 19 mounted on the control unit mounting portion 20 at a position close to the mounting flange 5b.
The control unit mounting portion 20 formed in the reduction gear box 4 includes a flat mounting surface 20a formed by the worm storage portion 12 and the upper side of the lower worm wheel storage portion 14, and the flat mounting surface 20a and the torque sensor. It is formed with a rectangular unit mounting surface 20b that is orthogonal to the flat mounting surface 20a formed on the upper surface of the storage portion 16 and that extends in the longitudinal direction in the left-right direction.

  As shown in FIG. 4, the control unit 19 mounted on the control unit mounting unit 20 includes a drive circuit that controls driving of the electric motor 5, a control circuit that receives a torque detection value of the torque sensor 15, and a battery voltage. A power supply circuit that converts the voltage into a predetermined voltage and supplies the voltage to the control circuit. Reference numeral 27 denotes a thermistor for detecting a temperature related to a heat generating part such as a drive circuit. The drive circuit, control circuit, power supply circuit, and thermistor 27 are provided in the control unit 19.

  Here, the control circuit is composed of a circuit including a microcomputer, and the motor control according to the steering torque is performed so as to generate the steering assist torque according to the value of the steering torque detected from the torque detection value of the torque sensor 15. In addition to the normal control function of generating a PWM drive signal with a duty ratio that realizes a target value of current (target control current value) and controlling the drive circuit, by reading the signal from the thermistor 27, the control unit 19 The overheat prevention function for preventing overheating in the control unit 19 is realized by monitoring the temperature state of the motor and forcibly lowering the motor control current below the target control current value as necessary. Yes. The details of this overheat prevention function will be described later.

  As shown in FIG. 3, the control unit 19 of the present embodiment includes a heat radiating case 21, an auxiliary heat radiating plate 22 integrated with the heat radiating case 21, and a first metal substrate 23 mounted in the heat radiating case 21. A second metal substrate 24 attached to the auxiliary heat radiating plate 22, an insulating substrate 25 attached in the heat radiating case so as to cover the first and second metal substrates 23, 24, and a cover 26. Yes.

The members constituting the control unit 19 will be described in detail with reference to FIG.
The heat dissipation case 21 is a substantially box-shaped member made of, for example, aluminum (aluminum alloy) die casting. A case mounting piece 21a provided with a screw passage hole is formed on the outer periphery of the heat radiating case 21 so as to protrude, and board mounting screw holes 21c are formed in the vicinity of the four corners of the rectangular bottom plate 21b. At the four corners of the bottom plate 21b, support portions 21d are formed which are in contact with the four corners of the insulating substrate 25 and support the insulating substrate 25, and board mounting screw holes 21e are formed above the support portion 21d. . A rectangular notch 21g is formed in one of the pair of wall plates 21f rising from the long side of the bottom plate 21b, and a support portion 21h for supporting the auxiliary heat radiating plate 22 is formed at the lower end corner of the notch. A heat sink mounting screw hole 21i is formed in the upper portion of the support portion 21h. A terminal block 40 that is electrically connected to the connection terminals 5 c and 5 d of the electric motor 5 is fixed to one side of the heat radiating case 21 in the longitudinal direction.

  The auxiliary heat radiating plate 22 extends in a direction perpendicular to the wall plate 22a and the wall plate 22a arranged flush with the wall plate 21f of the heat radiating case 21, and has an area larger than that of the bottom plate 21b of the heat radiating case 21. A screw passage hole 22c corresponding to the heat sink mounting screw hole 21i formed in the support portion 21h of the heat dissipation case 21 is formed in the vicinity of the wall plate 22a of the support plate 22b. Has been. Also, board mounting screw holes 22d are formed at the four corners of the support plate 22b.

  The first metal substrate 23 is a member in which an insulating layer is formed on the surface of an aluminum plate that is a base material, and a conductor pattern as a circuit conductor is formed thereon, and a drive circuit is formed on a predetermined portion of the conductor pattern. Circuit components constituting the part are mounted, and a thermistor 27 is disposed in the vicinity of the circuit components. Some circuit components of the drive circuit mounted on the first metal substrate 23 are an FET chip 28a as a switching element, an electric field capacitor 28b, and the like. A plurality of signal terminals 29 are erected on the first metal substrate 23 in a line. Further, screw passing holes 23 a corresponding to the board mounting screw holes 21 c of the heat dissipation case 21 are formed at the four corners of the first metal substrate 23. The first metal substrate 23 is formed with power terminals (not shown) connected to the terminal block 40 fixed to the heat radiating case 21.

  The second metal substrate 24 is also a member in which an insulating layer is formed on the surface of an aluminum plate that is a base material, and a conductor pattern as a circuit conductor is formed thereon, as shown in FIG. The remaining circuit components constituting the drive circuit are mounted on the part. The remaining circuit components constituting the drive circuit mounted on the second metal substrate 24 are electromagnetic relays 30. A plurality of signal terminals 31 are erected on the second metal substrate 24 in a line. Further, screw passage holes 24 a corresponding to the board mounting screw holes 22 d of the auxiliary heat radiating plate 22 are formed at the four corners of the second metal substrate 24.

  The insulating substrate 25 is a member in which a conductor pattern as a circuit conductor is formed on an insulating material such as a synthetic resin, and a power supply circuit and a control circuit are mounted on predetermined portions of the conductor pattern. The circuit component 32 constituting the power supply circuit is, for example, a regulator. Further, the circuit component 33 constituting the control circuit is, for example, a microcomputer chip or a transistor constituting an input / output circuit. In this insulating substrate 25, a plurality of through holes 34 and 35 into which a plurality of signal terminals 29 of the first metal substrate 23 and a plurality of signal terminals 31 of the second metal substrate 24 are fitted are formed in rows. . Further, screw passage holes 25 a corresponding to the board mounting screw holes 21 e formed in the support portion 21 d of the heat radiating case 21 are formed at the four corners of the insulating substrate 25. A female connector 36 for external wiring is fixed to the insulating substrate 25. A power supply male connector 46 (see FIG. 1) is connected to a battery (not shown) to the female connector 36, and is connected to a network such as a CAN for transmitting / receiving data to / from a control device of each part of the vehicle body. A signal connector (not shown) to be connected is connected.

The cover 26 is a box-shaped member that is formed by, for example, steel pressing or the like and covers the opening of the heat radiating case 21. On the outer periphery of the cover 26, a cover attachment piece 26a provided with a screw passage hole is formed so as to protrude.
In order to mount the control unit 19 having the above configuration on the control unit mounting portion 20, first, the first metal substrate 23 is brought into contact with the bottom plate 21 b of the heat radiating case 21, and board mounting screw holes 21 c provided at these four corners. And the 1st metal board | substrate 23 is fixed in the thermal radiation case 21 by screwing a screw (not shown) corresponding to the screw passage hole 23a. Then, the wall plate 22a of the auxiliary heat radiating plate 22 is fitted into the notch 21g of the heat radiating case 21, and the screw ( By screwing in (not shown), the auxiliary heat radiating plate 22 is fixed with the support plate 22b protruding into the heat radiating case 21. At this time, the support plate 22b is disposed at a position overlapping the FET chip 28a mounted on the first metal substrate 23 with a predetermined interval.

Next, the second metal substrate 24 is brought into contact with the support plate 22b of the auxiliary heat radiating plate 22, and screws (not shown) are screwed into the board mounting screw holes 22d and the screw passage holes 24a provided at the four corners. The two metal substrate 24 is fixed to the support plate 22b.
Next, the signal terminals 29 of the first metal substrate 23 and the signal terminals 31 of the second metal substrate 24 are fitted into the through holes 34 and 35 of the insulating substrate 25 and soldered, and screws provided at the four corners of the insulating substrate 25. The insulating substrate 25 is fixed in the heat dissipation case 21 by screwing a screw (not shown) after the passage hole 25a corresponds to the board mounting screw hole 21e formed in the support portion 21d of the heat dissipation case 21.

  Then, the cover 26 is mounted on the heat radiating case 21 so as to cover the opening of the heat radiating case 21, and the case mounting pieces 21 a and 26 a correspond to the screw holes 20 a 1 formed on the flat mounting surface 20 a of the control unit mounting portion 20. Then, the control unit 19 is mounted on the control unit mounting portion 20 by screwing the fixing bolt 37.

Here, as shown in FIG. 5, the drive circuit arranged in the control unit 19 is mounted on the second metal substrate 24 so as to overlap the FET chip 28a mounted on the first metal substrate 23 with a predetermined interval. The electromagnetic relay 30 is arranged. A thermistor 27 is disposed on the first metal substrate 23 at a position close to the FET chip 28a, and an electric field capacitor 28b is mounted on the opposite side of the FET chip 28a with the thermistor 27 interposed therebetween. ing. The electric field capacitor 28b is a position where the support plate 22b of the auxiliary heat radiating plate 22 fixing the second metal substrate 24 is not extended, and the insulating substrate 25 on which the power supply circuit 32 and the control circuit 33 are mounted. Is mounted on the first metal substrate 23 at a wide position.
The terminal block 40 of the control unit 19 and the connection terminals 5c and 5d of the electric motor 5 are electrically connected, and are covered with a synthetic resin terminal cover denoted by reference numeral 47 in FIG.

Next, the operation of the above embodiment will be described.
When electric power is supplied from the battery with the ignition switch (not shown) of the vehicle turned on, the control circuit of the control unit 19 generates a steering assist torque corresponding to the value of the steering torque detected from the torque detection value of the torque sensor 15. In order to achieve this, a PWM drive signal having a duty ratio that realizes a target value of the motor control current according to the steering torque is generated to control the drive circuit. Thereby, the electric motor 5 is driven to generate a necessary steering assist force by rotating in the forward or reverse direction.

  Therefore, a steering assist force corresponding to the steering torque of the steering wheel is generated from the electric motor 5, and this steering assist force is transmitted to the output of the steering shaft 2 via the worm 11 and the worm wheel 13, whereby the steering wheel Is steered with a light steering force.

Next, the overheat prevention function performed by the control circuit described above will be described with reference to FIGS.
FIG. 6 is a functional block diagram of the overheat prevention function. The motor current detection means 50 for detecting the motor current value controlling the electric motor 5, the motor control value detected by the motor current detection means 50, and the thermistor 27 Based on the detected junction temperature, the junction temperature calculation means 51 for calculating the junction temperature of the circuit components constituting the drive circuit, the storage means 52 for storing a table necessary for the overheat prevention mechanism, and the calculated junction temperature. The motor control current value is calculated based on the maximum control current value setting means 53 for calculating the maximum control current value of the electric motor and the torque detection value detected by the torque sensor 15 and the motor current value detected by the motor current detection means 50. Motor control current value calculation means 54 to be operated, and motor control current calculated by the motor control current value calculation means 54 And the maximum control current value set by the maximum control current value setting means 53, the current value setting means 55 for setting the smaller current value as the motor control current value, and the motor control current set by the current value setting means And motor drive control means 56 for controlling the current motor 5 based on the value.

The ambient temperature detecting means of the present invention corresponds to the thermistor 27, and the control current changing means of the present invention is the storage means 52, the maximum control current value setting means 53, the motor control current value calculating means 54, and the current value setting means 55. And the motor drive control means 56.
For example, the control circuit performs an overheat prevention process shown in the flowcharts of FIGS. These flowcharts are executed by timer interruption every sampling time ΔT set to about 10 msec, for example. In this flowchart, no particular communication step is provided, but the results obtained by the arithmetic processing are updated and stored in the storage means 52 as needed, and necessary information and programs are read from the storage means 52 as needed.

First, in step S1, the detected torque value detected by the torque sensor 15 is read.
Next, in step S <b> 2, the motor control current value calculation unit 54 calculates the motor control current value A <b> 1 based on the torque detection value detected from the torque sensor 15 and the motor current value detected by the motor current detection unit 50.
Next, the process proceeds to step S3, and the ambient temperature Ta detected by the thermistor 27 is read.
Next, the process proceeds to step S4, where the junction temperature calculation means 51 calculates the junction temperature Tj based on the ambient temperature Ta (junction temperature calculation processing routine of FIG. 8 described later).

  Next, the process proceeds to step S5, where the maximum control current value setting means 53 refers to the temperature protection table of FIG. 10 stored in the storage means 52, and the maximum current limit value A2 corresponding to the junction temperature Tj calculated in step 4 is reached. Set. The temperature protection table of FIG. 10 sets the maximum current limit value A2 to a low value when the junction temperature Tj is high, and sets the maximum current limit value A2 to a high value when the junction temperature Tj is low. It is.

  Next, the process proceeds to step S6, and the current value setting means 55 compares the motor control current value A1 calculated in step S2 with the maximum current limit value A2. In step S6, if the motor control current value A1 is larger than the maximum current limit value A2, the process proceeds to step S7. If the motor control current value A1 is less than the maximum current limit value A2, The process proceeds to step S8 without changing the motor control current value A1.

In step S7, which is shifted when the motor control current value A1 is larger than the maximum current limit value A2, the motor control current value A1 is changed to the maximum current limit value A2, and then the process shifts to step S8.
In step S8, the motor drive control unit 56 outputs the set motor control current value A1 to control the electric motor 5, and then returns to return.

  Here, in the junction temperature calculation processing routine shown in step S4, the junction temperature calculation means 51 executes the processing shown in FIG. In this junction temperature calculation processing routine, the junction temperature calculation table of FIG. The junction temperature calculation table of FIG. 9 shows the change in the temperature (hereinafter referred to as the first temperature) T1 of the FET chip 28a mounted on the first metal substrate 23 according to the change in the ambient temperature Ta, and the second metal substrate 24. This is data obtained by experiments in advance on changes in temperature (hereinafter referred to as second temperature) T2 of the mounted electromagnetic relay 30.

First, in step S20, the first temperature T1 corresponding to the ambient temperature Ta detected by the thermistor 27 is calculated with reference to the junction temperature calculation table of FIG.
Next, the process proceeds to step S21, and the second temperature T2 corresponding to the ambient temperature Ta detected by the thermistor 27 is calculated with reference to the junction temperature calculation table of FIG.
Next, the process proceeds to step S22, and the calculated first temperature T1 and second temperature T2 are compared. In step S22, if the first temperature T1 is larger than the second temperature T2, the process proceeds to step S23. If the first temperature T1 is equal to or lower than the second temperature T2, the process proceeds to step S24.

  In step S23 which shifts when the first temperature T1 is larger than the second temperature T2, the first temperature T1 is set to the junction temperature Tj, and then the flow shifts to return.

Moreover, in step S24 which transfers when the 1st temperature T1 is below 2nd temperature T2, after setting the 2nd temperature T2 to the junction temperature Tj, it transfers to a return.
Next, the effect of the control unit 19 in the electric power steering apparatus 1 of this embodiment will be described.
As shown in FIG. 5, the control unit 19 of the present embodiment includes an FET chip 28a and an electric field capacitor 28b that constitute part of the drive circuit mounted on the first metal substrate 23, and an electromagnetic relay that constitutes the rest of the drive circuit. 30 is mounted on the second metal substrate 24. The first metal substrate 23 is fixed on the bottom plate 21 c of the heat dissipation case 21, and the second metal substrate 24 is between the first metal substrate 23 and the insulating substrate 25 fixed so as to cover the opening of the heat dissipation case 21. Is fixed on a support plate 22b of an auxiliary heat radiating plate 22 integrated with the heat radiating case 21 so as to divide a part of the space.

  For this reason, even if the motor current for controlling the electric motor 5 becomes a large current, the FET chip 28a, the electric field capacitor 28b, and the electromagnetic relay 30 of the drive circuit are connected to the bottom plate 21c of the heat dissipation case 21 and the support plate 22b of the auxiliary heat dissipation plate 22. Since it is mounted on the first metal substrate 23 and the second metal substrate 24 fixed to each other, a sufficient heat radiation area of the drive circuit that self-heats with a large current can be secured.

  Further, the electromagnetic relay 30 mounted on the second metal substrate 24 fixed to the support plate 22b is spaced by a predetermined distance from the FET chip 28a mounted on the first metal substrate 23 fixed to the bottom plate 21b of the heat radiating case 21. Are arranged so as to overlap each other. Further, the electric field capacitor 28b having a height higher than that of the FET chip 28a is first extended so as to extend in a wide space between the first metal substrate 23 and the insulating substrate 25 where the support plate 22b does not extend. It is mounted on a metal substrate 23.

As described above, the control unit 19 of the present embodiment arranges a part of the circuit components (electromagnetic relay 30 and FET chip 28a) constituting the drive circuit in a layered manner, and the remaining circuit components (electric field capacitor) constituting the drive circuit. Since 28b) is arranged in a wide space in the control unit 19, the control unit 19 can be reduced in size and the vehicle mountability can be improved.
Therefore, the electric power steering apparatus 1 of the present embodiment is for increasing the motor current for controlling the electric motor 5 in order to increase the steering assist force according to the steering torque of the steering wheel, and for improving the vehicle mountability. Further, the control unit 19 can be downsized at the same time.

Next, the effect of the overheat prevention function performed by the control unit 19 of the present embodiment will be described.
As shown in FIGS. 7 and 8, in the overheat prevention function performed by the control circuit, when the junction temperature Tj of the circuit components constituting the drive circuit of the control unit 19 to be monitored for overheat is high, the electric motor 5 is changed to the maximum current limit value A2 (see FIG. 10) set in the temperature protection table, the steering assist force is reduced accordingly, and the steering wheel operation is increased accordingly. Although it becomes heavy, it is positive and reliable that circuit components (electromagnetic relay 30 and FET chip 28a) constituting the drive circuit mounted on the first metal substrate 24 and the second metal substrate 24 are deteriorated or damaged due to overheating. Can be avoided.

Further, the junction temperature Tj of the circuit components constituting the drive circuit is the first temperature T1 of the FET chip 28a mounted on the first metal substrate 24 and the first temperature of the electromagnetic relay 30 mounted on the second metal substrate 24. Since the higher temperature value of the two temperatures T2 is set, overheat protection of the drive circuit can be performed with high accuracy.
In the above embodiment, the signal terminal 29 of the first metal substrate 23 and the signal terminal 31 of the second metal substrate 24 are fitted into the through holes 34 and 35 of the insulating substrate 25 and soldered. By electrically connecting the insulating substrate 25 and the first and second metal substrates 23 and 24 by using the molded conductive plate, it is possible to promote downsizing of the control unit 19 and further improve vehicle mountability. Can do.

  In the above embodiment, the case where the present invention is applied to a right-hand drive vehicle has been described. However, the present invention is not limited to this, and when applied to a left-hand drive vehicle, the reduction gear box 4 and the electric motor 5 are used. The control unit 19 is arranged symmetrically with respect to the vertical plane passing through the central axis of the steering column 3, that is, the electric motor 5 is arranged on the right side of the control unit 19, and the female connector 36 and the terminal block 40 of the control unit 19 are connected. The electric motor 5 may be disposed on the left side, and the electric connector 5 and the female connector 36 and the terminal block 40 may be disposed on the vehicle inner side.

  Further, in the above embodiment, the so-called electromechanical integrated electric power steering apparatus 1 in which the control unit 19 is mounted on the outer periphery of the reduction gear box 4 has been described. However, the small control using the metal substrates 23 and 24 for the heat radiating case 21 is described. If it is a unit, not only the said structure but the same effect can be show | played also when mounting the control unit 19 in a vehicle independently.

  DESCRIPTION OF SYMBOLS 1 ... Electric power steering device, 2 ... Steering shaft, 2a ... Input shaft, 2b ... Torsion bar, 2c ... Output shaft, 3 ... Steering column, 3a ... Inner tube, 3b ... Outer tube, 4 ... Reduction gear box, 4b ... Support part, 5 ... Electric motor, 5b ... Mounting flange, 5c, 5d ... Connection terminal, 6 ... Upper mounting bracket, 6a ... Mounting plate part, 6b ... Supporting plate part, 6c ... Tilt mechanism, 6g ... Tilt lever, 7 ... Lower mounting bracket, 7a ... Mounting plate portion, 7b ... Support plate portion, 7c ... Pivot, 11 ... Worm, 12 ... Worm housing portion, 13 ... Worm wheel, 14 ... Worm wheel housing portion, 15 ... Torque sensor, 15c-15f ... External connection terminal, 16 ... Torque sensor housing, 17 ... Motor mounting, 18 ... Column mounting, 19 ... Control unit, 20 ... Control unit mounting 20a ... flat mounting surface, 20a1 ... screw hole, 20b ... unit mounting surface, 21 ... heat dissipation case, 21a ... case mounting piece, 21a, 26a ... case mounting piece, 21b ... bottom plate, 21c ... board mounting screw hole, 21c ... bottom plate, 21d ... support portion, 21e ... board mounting screw hole, 21f ... wall plate, 21h ... support portion, 21i ... heat sink mounting screw hole, 22 ... auxiliary heat sink, 22a ... wall plate, 22b ... support plate , 22c: screw passage hole, 22d: screw hole for board attachment, 23 ... first metal substrate, 23a ... screw passage hole, 24 ... second metal substrate, 24a ... screw passage hole, 25 ... insulating substrate, 25a ... screw passage Hole, 26 ... Cover, 26a ... Cover mounting piece, 27 ... Thermistor, 28a ... FET chip, 28b ... Electric field capacitor, 29 ... Signal terminal, 30 ... Electromagnetic relay, 31 ... Signal terminal, 32 ... Power supply circuit 33 ... Control circuit parts, 34, 35 ... Through hole, 36 ... Female connector, 37 ... Fixing bolt, 40 ... Terminal block, 46 ... Male connector for power supply, 47 ... Terminal cover, 50 ... Motor current detection means , 51 ... junction temperature calculation means, 52 ... storage means, 53 ... maximum control current value setting means, 54 ... motor control current value calculation means, 55 ... current value setting means, 56 ... motor drive control means

Claims (6)

A steering column having a steering shaft to which a steering torque is transmitted; an electric motor that transmits a steering assist force to the steering shaft via a reduction mechanism in a reduction gear box; and a control unit that controls the electric motor. In the electric power steering apparatus provided,
The control unit includes a heat radiating case having an opening, a first metal substrate fixed to a bottom surface in the heat radiating case, and a support plate overlapping a part of the first metal substrate with a predetermined space. The auxiliary heat sink fixed to the heat dissipation case, the second metal substrate fixed on the support plate, the opening of the heat dissipation case to cover the first metal substrate and the second metal substrate An insulating substrate fixed on the part side, a part of the first metal substrate that overlaps with the support plate and a part of a component that constitutes a drive circuit that is mounted on a portion that does not overlap with the support plate; An electric motor comprising: the remaining components constituting the drive circuit mounted on the second metal substrate; and components constituting a control circuit and a power supply circuit mounted on the insulating substrate. Power Steering system.   The parts constituting the drive circuit having a low height are mounted on the portion of the first metal substrate that overlaps the support plate and the second metal substrate, and overlaps the support plate of the first metal substrate. 2. The electric power steering apparatus according to claim 1, wherein a part constituting the driving circuit having a high height is mounted on a portion not provided.   3. The electric motor according to claim 1, wherein the control unit has an overheat prevention function for preventing overheating of components constituting the drive circuit mounted on the first and second metal substrates. Power steering device.   The overheat prevention function includes an ambient temperature detection means for detecting an ambient temperature of components constituting the drive circuit mounted on the first and second metal substrates, and the drive circuit is configured based on the ambient temperature detection means. Junction temperature calculating means for calculating the junction temperature of the parts to be controlled, and control current changing means for changing the control current of the electric motor based on the junction temperature calculated by the junction temperature calculating means, The electric power steering apparatus according to claim 3. The ambient temperature detection means is disposed on the first metal substrate proximate to the second metal substrate;
The junction temperature calculation means sets the ambient temperature detected by the ambient temperature detection means as the first junction temperature of a part of the drive circuit mounted on the first metal substrate, and the ambient temperature detection means The second junction temperature of the remaining components constituting the drive circuit mounted on the second metal substrate based on the detected ambient temperature is estimated and calculated,
5. The electric power steering apparatus according to claim 4, wherein the control current changing unit changes the control current of the electric motor based on a higher one of the first junction temperature and the second junction temperature.   The said junction temperature calculation means correct | amends the said 1st junction temperature and the said 2nd junction temperature based on the thermal resistance, the heat capacity, etc. of the components of the said drive circuit memorize | stored beforehand. Electric power steering device.

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