JP4054965B2 - Motor start control device and automatic transmission provided with the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a position sensor that detects a range position of a drive machine that is set according to a driver's operation in a drive machine that is connected to a prime mover such as an engine or a motor, and is electrically connected to the position sensor. A control device for determining a range position based on a signal from at least a position sensor, and a motor start control device for driving (permitting) the motor based on a non-traveling range determination signal from the control device, and It belongs to the technical field of automatic transmissions equipped with prime mover start control devices.
[0002]
In this case, the drive unit shifts and outputs the power of a prime mover such as an engine to a predetermined power within a range set by a driver's operation, and automatically performs a start operation and a shift operation as described above. Machine (hereinafter also referred to as A / T), a semi-automatic transmission that automates the starting operation and manually switches the gear position, a continuously variable transmission that can continuously control the gear ratio of the gear speed, and the like.
[0003]
[Prior art]
The A / T mounted on the vehicle is operated by a shift device operated by the driver of the hydraulic control device and a CPU that controls the A / T based on a vehicle state detection signal such as a detection signal of the vehicle running state. It is controlled by doing.
[0004]
In a vehicle equipped with A / T, the range position of A / T is detected by a position sensor, and the CPU determines the range position based on a detection signal from the position sensor. In this case, the position sensor has a neutral start switch (hereinafter also referred to as N switch), and this N switch is a non-traveling range position where A / T is in the parking (P) range position or neutral (N) range position. When the CPU determines that the A / T is set to the non-traveling range position based on the output signal from the N switch, the determination signal is output to the engine. Is output to the starter motor start circuit so that the starter motor can be driven.
[0005]
Japanese Patent Laid-Open No. 5-196130 proposes to simplify the wiring structure and make the whole compact by integrating the position sensor and the CPU. According to the integrated structure of the position sensor and the CPU disclosed in this publication, it is possible to eliminate complicated harness connection, to reduce the cost, to make the whole compact, and to improve the mountability.
[0006]
Further, in order to perform integrated control as a vehicle, conventionally, communication between a CPU and an external device such as an engine control device is performed. In this case, communication between the CPU and the external device is performed via a controller area network (CAN) which is a serial communication protocol having two serial communication lines.
[0007]
[Problems to be solved by the invention]
By the way, the above-mentioned publication which discloses an integrated structure of a position sensor and a CPU discloses that an engine starter signal is output from the CPU in response to a detection signal from an N switch. However, in this prior art, only outputting a starter signal from the CPU is disclosed, and no specific connection line is disclosed.
[0008]
Therefore, it is conceivable to supply a starter signal from the CPU to the starter motor start circuit by the above-described CAN that connects the CPU and the external device. However, since the CAN is connected to the equipment in the vehicle as described above, that is, it is stretched around the vehicle, it is very long and has a high probability of failure such as disconnection. For this reason, at the time of such a failure, there exists a problem that an engine cannot be driven.
[0009]
The N switch is conventionally provided in a relay circuit that opens and closes a starter motor start circuit or in the start circuit itself. By the way, when the N switch detects the non-traveling range position of A / T and the CPU closes the contact of the starting circuit, a large current for driving the starter motor flows in the starting circuit. For this reason, when the N switch is interposed in the starter motor relay circuit or the starting circuit in this way, in the integrated structure of the N switch and CPU as disclosed in the above-mentioned publication, a large current for driving the starter motor is obtained. May adversely affect a CPU operating with a small current. However, the above-mentioned publication does not disclose such a problem, nor does it disclose any special consideration for this problem, and the prior art disclosed in this publication does not solve this problem. difficult.
[0010]
The present invention has been made in view of such circumstances, and its purpose is from a motor driving means or a CPU for enabling the motor to start even at the time of a failure such as a connection line to an external device. It is to provide a prime mover start control device capable of reliably and quickly supplying a range position determination signal (start permission signal) to a prime mover drive means or a start circuit of a prime mover, and an automatic transmission including the same.
[0011]
Another object of the present invention is to provide an automatic transmission provided with a prime mover start control device that can prevent the influence of a large current flowing in the starter circuit of the prime mover drive means on the CPU even if the position sensor and the CPU are integrated. It is.
[0012]
Still another object of the present invention is to provide an automatic transmission having a prime mover start control device that can reliably drive prime mover drive means even if a non-contact sensor is used as a position sensor.
[0013]
[Means for Solving the Problems]
  In order to solve the above-mentioned problem, a motor start control device according to the first aspect of the present invention includes a position sensor for detecting a range position of a driving machine coupled to a motor driven by a motor driving means, and the position sensor and the electric motor. And a control device for determining a range position based on at least a signal from the position sensor, and the control device and an external device that is a plurality of devices for controlling each device in the vehicle, respectively. Are connected by a first connection line, and the control device and the starting circuit of the motor driving means are connected by a second connection line different from the first connection line.Via the switching elementThe first connection line is configured by a network, and the network connects the control device and the plurality of devices, and the second connection line is connected to the position sensor. The start permission signal for enabling the starter circuit of the prime mover driving means to start based on the signal is transmitted to the starter circuit, and the second connection line has a higher voltage than the first connection line. It is a high voltage supply line to be supplied.
[0014]
  The invention of claim 2Motor start control deviceIs a position sensor for detecting a range position of a drive unit connected to a prime mover driven by a prime mover drive means, and is electrically connected to the position sensor, and determines a range position based on at least a signal from the position sensor. And a control deviceAnd a plurality of devices for controlling each device in the vehicle.With external devicesButConnected by the first connection lineAnd the control device and the starting circuit of the prime mover driving means are connected via a relay circuit that controls opening and closing of the starting circuit with a second connection line different from the first connection line, The first connection line is configured by a network, and the network connects the control device and the plurality of devices, and the second connection line is based on a signal from the position sensor. A high-voltage supply line for transmitting a start permission signal for enabling start of the starting circuit of the motor driving means to the relay circuit, and for supplying a voltage higher than that of the first connection line to the second connection line. IsIt is characterized by that.
[0015]
  Furthermore,The invention of claim 3The control device further controls the drive unit based on a vehicle state detection signal such as a detection signal of a running state of the vehicle.
[0016]
  Furthermore, the invention of claim 4The control device is a control device with a position sensor in which the position sensor is integrated.It is characterized by that.
[0017]
  Furthermore, the invention of claim 5The control device with a position sensor has a connection port for connecting to the external device, and the starting circuit is connected to the connection port via the second connection line.It is characterized by that.
[0018]
  Furthermore, the invention of claim 6The control device with a position sensor is provided integrally with the driving machine.
[0019]
  Furthermore, the invention of claim 7The control device with a position sensor has a second connection port for connecting to the driving machine.It is characterized by that.
[0020]
  Further, the prime mover start control device of the invention of claim 8 is a position sensor for detecting a range position of a drive unit coupled to the prime mover driven by the prime mover drive means, and is electrically connected to the position sensor, and at least the A control device that determines a range position based on a signal from a position sensor, and the control device and an external device that is a plurality of devices for controlling each device in the vehicle are connected by a first connection line. The control device and the starting circuit of the motor driving means are connected with a second connection line different from the first connection line.Via the switching elementThe first connection line is configured by a network, and the network connects the control device and the plurality of devices, and the second connection line is connected to the position sensor. The start permission signal for enabling the starter circuit of the prime mover driving means to start based on the signal is transmitted to the starter circuit, and the second connection line has a higher voltage than the first connection line. It is a high voltage supply line to be supplied.
[0021]
  Furthermore, the invention of claim 9Motor start control deviceIsA position sensor for detecting a range position of a drive unit coupled to a prime mover driven by a prime mover drive means, and a control electrically connected to the position sensor and determining the range position based on at least a signal from the position sensor A control device and an external device, which is a plurality of devices for controlling each device in the vehicle, are connected by a first connection line, and the control device and starting of the motor driving means A second connection line different from the first connection line is connected via a relay circuit that controls opening and closing of the starting circuit, and the first connection line is configured by a network. A network connects the control device and the plurality of devices, and the second connection line is connected to the prime mover based on a signal from the position sensor. A start permission signal for enabling the start circuit of the driving means to start is transmitted to the relay circuit, and the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line. is thereIt is characterized by that.
[0022]
  Furthermore, the invention of claim 10 providesThe control device further controls the drive unit based on a vehicle state detection signal such as a detection signal of a running state of the vehicle.It is characterized by that.
[0023]
  Furthermore, the invention of claim 11The control device is a control device with a position sensor in which the position sensor is integrated.It is characterized by that.
[0024]
  Furthermore, the invention of claim 12The control device with a position sensor has a connection port for connecting to the external device, and the starting circuit is connected to the connection port via the second connection line.It is characterized by that.
[0025]
  Furthermore, the invention of claim 13The control device with a position sensor is provided integrally with the driving machine.
[0026]
  Furthermore, the invention of claim 14The control device with a position sensor has a second connection port for connecting to the driving machine.It is characterized by that.
[0027]
Furthermore, in the invention of claim 15, the second connection line is connected to the relay coil interposed in the relay circuit, and the relay coil is connected to the relay coil by a signal supplied via the second connection line. The relay circuit is operated by supplying a relay driving current.
[0028]
Furthermore, the invention of claim 16 is characterized in that the control device is interposed in the relay circuit.
[0029]
Further, the invention of claim 17 is characterized in that a starter switch of an ignition switch of the prime mover is interposed in the relay circuit.
[0031]
  Further claims18In the invention, the first connection line is connected to the vehicle state detection signal of the external device.IssueIt is a signal line for transmission.
[0033]
  Further claims19According to the present invention, the first connection line is a serial communication line.
[0034]
  Further claims20In this invention, the determination signal of the range position from the control device is inputted to the second connection line, and the determination signal is a signal for controlling conduction of the starting circuit with the power supply device. It is characterized by being.
[0035]
  Further claims21According to the present invention, the position sensor is a non-contact switch.
[0036]
  Further claims22The non-contact switch is characterized in that the non-contact switch includes a magnetic field generating means for changing a magnetic field by a driver's operation and a sensor for changing an output by the displacement of the magnetic field.
[0037]
  Further claims23The automatic transmission according to the present invention is the first aspect.22The motor start control device according to any one of the above is provided, and the drive unit is configured.
[0038]
[Operation and effect of the invention]
  According to the prime mover start control device of each of the inventions according to claims 1 to 22 configured as described above, the start permission for enabling the prime mover drive means or the starter circuit of the prime mover to be started by the control device based on the signal from the position sensor A second connecting line for transmitting the signal connects the control device and the starting circuit.Via the switching elementAlternatively, the connection is made through the relay circuit of the starting circuit and is different from the first connection line for connecting the control device and the external device, so the connection for supplying the start permission signal from the control device to the starting circuit The line can be a dedicated connection line only for supplying the start permission signal. As a result, no signal other than the start permission signal to the start circuit flows through this dedicated connection line, so that the start permission signal is transmitted to the start circuit faster, and as a result, the range position of the drive machine The prime mover can be driven quickly according to the situation.
  Further, a network composed of a first connection line different from the above-described second connection line is used to control an engine control module (hereinafter also referred to as an ECM (Engine Control Module)) or an anti-vehicle control device and an external device. Since it is connected to multiple devices that control each device such as the lock control module {hereinafter also referred to as ABS (Anti Braking System)}, the drive control of the prime mover according to the range position of the drive machine and the interior of the vehicle It becomes possible to control each device in an integrated manner.
  Further, the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line. By the way, the 1st connection line comprised from the above-mentioned CAN etc. and connected to the external device which is a vehicle system is set to the comparatively low voltage. On the other hand, when the start circuit is opened and closed using a relay circuit, the start circuit requires a relatively high voltage. Therefore, in order to reliably close the start circuit, it is necessary to supply a high voltage to some extent. Therefore, a voltage higher than the voltage supplied to the first connection line is supplied to the second connection line connected to the starting circuit or the relay circuit. As described above, the second connection line is connected to the high voltage. By using the supply line, the high voltage can be reliably applied without breaking the second connection line, and the second connection line has excellent durability against such a high voltage. can do. In addition, the cost can be reduced by making only the second connection line excellent in durability.
[0039]
In addition, by using a dedicated connection line for the start permission signal to the start circuit, even if another device such as an external device or another line fails, the prime mover can be surely not affected by this failure. Can drive. Thereby, the driving reliability of the prime mover is improved even during such a failure.
[0040]
  In particular, according to the inventions of claims 2 and 9,Since the continuity between the power supply device of the starting circuit and the prime mover driving means is controlled by a relay circuit different from the starting circuit, even if a large current for driving the prime mover driving means flows in the starting circuit, the relay circuit Can be prevented from being affected by this large current.
  According to the inventions of claims 3 and 10,Since the drive unit is controlled by the control unit based on the vehicle state detection signal such as the detection signal of the running state of the vehicle, the control unit for determining the range position of the drive unit and the engine speed, throttle opening, etc. A controller for a drive machine that controls the drive machine based on a vehicle state detection signal such as a detection signal of the running state of the vehicle can be integrated into the control apparatus, so that the number of parts can be reduced and an increase in cost can be prevented.
[0041]
  Claims4and11According to the invention, since the control device with a position sensor in which the control device for determining the range position of the drive machine and the position sensor are integrated is configured, the combination of the control device and the position sensor can be made compact and wired. Can be simplified.
[0042]
  Further claims5and12According to the invention, since the second connection line for connecting to the starting circuit of the motor driving means is connected to the connection port for connection with the external device provided in the control device with position sensor, the position The sensor-equipped control device can be dispensed with separately providing a dedicated connection port for connecting to the starter circuit, and the cost can be reduced.
[0043]
  Further claims6and13According to the invention, since the control device with a position sensor is provided integrally with the driving machine, the second connection line can be shortened and the second connection line does not have to be thicker than the first connection line. In addition, it is possible to effectively reduce the occurrence of problems such as disconnection and to reduce costs.
[0044]
  Further claims7and14According to the invention, the second connection port for connecting to the drive machine is connected to the starting circuit of the motor drive means (hereinafter also referred to as the first connection port) in the control device with position sensor. ), It can be connected to the driving machine through the second connection port. Accordingly, the second connection port can be arranged regardless of the position of the first connection port, that is, the prime mover driving means, and the degree of freedom of arrangement of the second connection port can be increased.
[0046]
According to the fifteenth aspect of the present invention, the relay driving current is output to the relay coil interposed in the relay circuit by the predetermined range position determination signal of the driving machine by the control device. It can be reliably operated in the range position.
[0047]
Furthermore, according to the invention of claim 16, since the control device is interposed in a relay circuit different from the start circuit, the influence on the control device due to a large current flowing in the start circuit can be prevented.
[0048]
Further, according to the invention of claim 17, since the starter switch of the ignition switch is interposed in the relay circuit through which a current smaller than the current of the starting circuit flows, the starter switch of the ignition switch is a small switch for small current. The motor drive means can be reliably driven with this small switch.
[0050]
  Claims18According to the invention, since the vehicle state detection signal of the external device is transmitted by the first connection line, the driving machine is controlled based on the vehicle state detection signal.Canit can.
[0052]
  Further claims19According to the invention, since the first connection line is a serial communication line, a signal is input to the first connection line by detecting a voltage difference between the two communication lines constituting the serial communication line. Can be determined. Therefore, even if noise enters the first connection line, only the voltage between the two communication lines rises, and no difference due to noise occurs in the voltage difference between the two communication lines. It is possible to prevent erroneous determination due to noise.
[0053]
  Further claims20According to the invention, since the determination signal of the range position from the control device is input to the second connection line, the conduction between the prime mover driving means and the power supply device of the starting circuit is controlled by the determination signal. By making the power supply device conductive to the prime mover driving means such as a starter motor at the predetermined range position, the prime mover can be started reliably.
[0054]
  Further claims21According to the invention, since the position sensor is configured with a non-contact switch, the range position of the driving machine is detected with a non-contact switch having a simple and compact configuration and wear resistance, and the control device uses the detection signal as a detection signal. When the predetermined range position of the driving machine is determined based on this, the power supply device is made conductive to the driving motor driving means, and the driving motor driving means can be started to reliably start the driving motor.
[0055]
  Further claims22According to the invention, since the non-contact switch is composed of the magnetic field generating means for changing the magnetic field by the operation of the driver and the sensor for changing the output by the displacement of the magnetic field, the magnetic field for continuously displacing the range position. Can be detected by the output of.
[0056]
  Further claims23According to the automatic transmission of the present invention, claims 1 to22Therefore, the automatic transmission and the prime mover start control device can be driven quickly and reliably according to the range position of the automatic transmission. Can be formed compactly.
[0057]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In this specification, “start” and “drive” are used, but as will be described later, the prime mover driving means is first driven, and the prime mover is driven by the drive of the prime mover driving means. Only the two terms are used, there is no particular difference between them, and they have substantially the same meaning.
[0058]
FIG. 1 is a block diagram schematically showing a first example of an embodiment of a prime mover start control device according to the present invention.
As shown in FIG. 1, the prime mover start control device 101 of the first example includes a position sensor 7 that detects the range position of the drive machine 102 and a control device that determines the range position of the drive machine 102 (hereinafter also referred to as CPU). 5), a prime mover driving means 104 for driving the prime mover 103, a starting circuit (hereinafter also referred to as a starter circuit) 105 for starting the prime mover driving means 104, and a relay circuit 106 for controlling the opening and closing of the starting circuit 105. Has been.
[0059]
The driving device 102 is, for example, an automatic transmission, a semi-automatic transmission, a continuously variable transmission, or the like, and is set to an appropriate range position and shifts and outputs the power of the prime mover 103 to appropriate power.
The position sensor 7 detects a set range position of the driving machine 102 and outputs a range position detection signal. The range position here is, for example, parking (P), reverse (R), neutral (N), drive (D), and the like.
[0060]
The CPU 5 is supplied with a range position detection signal from the position sensor 7, determines the range position of the drive unit 102 based on this signal, and outputs the determination signal to the relay circuit 106. The CPU 5 controls the drive unit 102 based on a signal from the external device 107 and outputs a determination signal for the range position of the drive unit 102 to the external device 107. The external device 107 is a vehicle system including a plurality of devices for controlling each device in the vehicle, and includes, for example, an engine control module, an antilock brake module (ABS), door opening / closing detection means, brake operation detection means, and the like. Therefore, for example, based on a vehicle state detection signal such as a detection signal of a vehicle running state such as the number of revolutions of the engine 103 that is the prime mover 103, the throttle opening degree of the engine, the anti-lock control, the door open / close state, and the brake operation state. 102 is controlled.
[0061]
The prime mover 103 generates power such as an engine.
The prime mover driving means 104 drives the prime mover 103 and is, for example, an engine starter motor.
[0062]
The starting circuit 105 is a part of the power supply device 108 and the conduction means 109, and has an open / close switch (described later) that controls conduction between the power supply device 108 and the prime mover drive means 104. When this open / close switch is off, When the power supply device 108 and the prime mover driving means 104 are cut off and the open / close switch is on, the power supply device 108 and the prime mover driving means 104 are allowed to conduct.
[0063]
The relay circuit 106 is another part of the conduction means 109, and has switch operation means (described later) for opening and closing the open / close switch of the start circuit 105. This switch operation means is supplied with a determination signal of a predetermined range position from the CPU 5. When activated, the switch is turned on. In the first example, an ignition switch 110 is interposed in the relay circuit 106.
[0064]
FIG. 2 is a diagram schematically showing a part of the prime mover start control device of the first example shown in FIG.
As shown in FIG. 2, the prime mover start control device 101 of the first example is configured as a control device with a position sensor in which the position sensor 7 and the CPU 5 are provided integrally. The control device constitutes an A / T transmission control module {hereinafter also referred to as TCM (Transmission Control Module)} 112.
[0065]
The position sensor 7 and the CPU 5 are connected by three signal lines 1a, 1b, 1c. The signal line 1a has a constant voltage V_ccIs supplied, and this constant voltage V_ccIs a substitute for the power supply voltage VB because the power supply voltage (battery voltage) VB varies greatly. Of course, it goes without saying that this power supply voltage VB can also be used. The signal line 1b outputs a position signal indicating the A / T range position output from the position sensor 7 to P._osIs a position signal line 1b for supplying to the CPU 5. Further, the signal line 1c is grounded (ground: GRD). Note that two position sensors 7 may be provided in order to avoid erroneous detection due to failure such as disconnection of the position signal line 1b or failure of the position sensor 7, but in this case, 4 signal lines are provided. It is necessary to provide this (only one position signal line 1b is added).
[0066]
The TCM 112 includes an A / T connection connector (corresponding to the second connection port of the present invention) 8 and a vehicle system connection connector (corresponding to the connection port of the present invention) 9 respectively connected to the CPU 5. One A / T connection connector 8 is connected to A / T2. The other A / T connector 8 is connected to a first connection line 113 and a second connection line 114 different from the first connection line 113.
[0067]
  The first connection line 113 is a serial communication line, and is composed of a power train high speed controller area network (High Speed CAN) 115 and a body low speed controller area network (Low Speed CAN) 116. The high-speed controller area network 115 is connected to the vehicle system 3 such as the ECM 117 and the ABS 118, and the low-speed controller area network 116 is connected to a door module (DOOR) 119 that detects the opening and closing of the door. Has been.Therefore, the first connection line 113 is a vehicle such as a detection signal of the running state of the vehicle such as the rotational speed of the engine which is the prime mover 103, the throttle opening degree of the engine, the antilock control, the door opening / closing state, the brake operating state, etc. It is a signal line for transmitting a state detection signal and a control signal for the drive unit 102.
[0068]
The serial communication line constituting the first connection line 113 is composed of two communication lines, and a signal is input to the first connection line 113 by detecting a voltage difference between the two communication lines. Can be judged. Therefore, even if noise enters the first connection line 113, only the voltage between the two communication lines rises, and no difference due to noise occurs in the voltage difference between the two communication lines. This erroneous determination due to noise can be prevented.
[0069]
The relay circuit 106 is connected to the second connection line 114. The second connection line 114 is configured as a high voltage supply line capable of supplying a voltage higher than the voltage of the first connection line 113.
[0070]
FIG. 3 is a diagram schematically showing an electrical connection structure in A / T in which the control device with a position sensor of the prime mover start control device 101 of the first example of the embodiment of the present invention is employed, and FIG. The top view which shows the control apparatus with a position sensor of a 1st example, FIG. 5 is sectional drawing which follows the VV line in FIG.
As shown in FIG. 3, the electrical connection structure in the A / T of the first example is the same as that of the control device 1 with position sensor, A / T2 controlled by the control device 1 with position sensor, and the control device with position sensor. 1, a vehicle system (corresponding to an external device of the present invention) 3 for supplying vehicle travel information 1 and a relay circuit 106 are electrically connected to each other.
[0071]
  As shown in detail in FIGS. 4 and 5, the control device with position sensor 1 includes a casing 4, and a CPU 5 that controls the shift of A / T 2 and determines the range position of A / T 2 in the casing 4. A position sensor 7 for detecting the rotational position of the manual shaft 6 of the A / T, that is, the range position of A / T2, which is operated by the driver's shift lever operation, shift switch operation, etc., and which is displaced according to this operation; / T connection connector 8 (corresponding to the second connection port of the present invention) and a vehicle system connection connector 9 (input of the present invention) to which a detection signal of the vehicle running state such as engine speed, oil temperature, etc. Equivalent to a connection port).This position sensor-equipped control apparatus 1 is provided integrally with A / T2.
[0072]
The CPU 5 includes a rectangular control substrate 10 made of a substrate such as a ceramic substrate, which has higher heat resistance and heat dissipation than the connection substrate 14 described later, in order to improve environmental resistance. A plurality of circuit chips (elements) mainly composed of a microcomputer are arranged on the control board 10, and each circuit chip is, for example, a terminal group arranged in a concentrated manner along two sides of the control board 10. 10a, 10b, 10c are included.
[0073]
As shown in FIG. 5, the position sensor 7 is fixed to the manual shaft 6 and can be rotated integrally with the manual shaft 6, and the position sensor 7 is fixed to the movable element 11 and can be rotated integrally with the movable element 11. A permanent magnet (corresponding to the magnetic field generating means of the present invention) 12 and a displacement of the magnetic field caused by the rotation of the permanent magnet 12 is detected in a non-contact manner with the permanent magnet 12, for example, a Hall element (Hall IC) that generates an electromotive force. ) And the like (corresponding to the sensor of the present invention) 13.
[0074]
Therefore, when the manual shaft 6 rotates in response to the shift operation performed by the driver, the relative position of the permanent magnet 12 and the magnetic sensor 13 changes, that is, the magnetic field of the permanent magnet 12 is displaced. A voltage value corresponding to the displacement of the magnetic field is output. Since this voltage value corresponds to the shift range position set by the driver's shift operation, the shift range position can be detected from this voltage value.
[0075]
As shown in FIG. 4, the position sensor 7 is provided with an output circuit section 7a for outputting a voltage signal from the magnetic sensor 13, and the output circuit section 7a is constituted by a substrate having a conducting wire, and this conducting wire. Is electrically connected to the conductive wire of the connection board 14 and is output to the connection board 14 from the output circuit portion 7a.
[0076]
As shown in FIG. 6, the vehicle system connection connector 9 is formed as a male connector, and includes a large number of input / output terminals 9a, 9a,. Although not shown, the A / T connection connector 8 is similarly formed as a male connector and includes a number of input / output terminals protruding outward.
[0077]
Further, on the connection board 14, three circuit terminal groups 14 a, 14 b, 14 c correspond to the three circuit terminal groups 10 a, 10 b, 10 c of the control board 10, and are on the long side and the short side of the control board 10. Are arranged close to each other. The circuit terminals of these circuit terminal groups 14a, 14b, and 14c are connected to the magnetic sensor 13 of the position sensor 7, the A / T connection connector 8, and the vehicle system connection connector 9 via the wiring of the connection board 14, respectively. It can be electrically connected to either of the input / output terminals.
[0078]
As shown in FIG. 5, the A / T connection connector 8 is electrically and directly connected to an A / T side connector 15 attached and fixed to an A / T case (not shown). Connected to the A / T side connector 15 is a wire harness 18 in which wirings of various sensors 16 in the A / T case and solenoids 17 attached to the valve body in the A / T case are combined. ing.
[0079]
FIG. 7 is a diagram partially and schematically showing an example of a specific configuration of the prime mover start control device of the first example.
As shown in FIG. 7, the control device with position sensor 1 constituting the TCM 112 in the prime mover start control device 101 of the first example includes a switching element 122 formed of an FET transistor between the CPU 5 and the vehicle system connector 9. Is intervening. The switching element 122 is a component of the relay circuit 106, and is turned off when the off signal is supplied from the CPU 5, and is turned on when the on signal is supplied. Yes. In this case, the ON / OFF signal from the CPU 5 is an ON signal when the A / T2 range position is set to a predetermined range {parking (P) range and neutral (N) range which are non-traveling ranges} positions. Further, when a range position other than the predetermined range position is set, an off signal is given.
[0080]
In the first example, the switching element 122 is provided in the control device with position sensor 1 and a part of the control device with position sensor 1 constitutes the relay circuit 106. It can also be provided so as to be connected to the outside of the control device with position sensor 1, that is, to the second connection line 114. In this case, the position sensor control apparatus 1 does not constitute the relay circuit 106.
[0081]
The second connection line 114 connected to the vehicle system connection connector 9 is connected to the first relay 123 of the relay circuit 106. That is, the first relay 123 includes a relay coil 124 that operates when current is supplied to generate a magnetic force, and a normally open opening / closing switch 125 that is operated (turned on) and closed by the magnetic force of the relay coil 124. Yes. A second connection line 114 is connected to one end of the relay coil 124, and a power supply device 126 in the vehicle is connected to the other end of the relay coil 124.
[0082]
Therefore, in the first relay 123, when the switching element 122 is turned on, the power of the power supply device 126 is dropped in voltage and applied to the relay coil 124, whereby a current flows through the relay coil 124 and the relay coil 124 operates. Thus, a magnetic force is generated and the open / close switch 125 is closed. In other words, the start permission signal is transmitted to the relay coil 124 via the second connection line 114.
[0083]
A contact on one side of the opening / closing switch 125 is connected to the power supply device 127 in the relay circuit 106, and a contact on the other side of the opening / closing switch 125 is connected to a contact on one side of the ignition switch 110 disposed in the relay circuit 106. Has been. The contact on the other side of the ignition switch 110 is connected to the second relay 128. That is, the second relay 128 constitutes the above-described conduction means 109, is a component of the relay circuit 106, and is a component of the starter circuit 105 and a relay coil 129 that operates when current is supplied to generate magnetic force. And a normally open on / off switch 130 that is closed by being actuated (turned on) by the magnetic force of the relay coil 129. The ignition switch 110 is connected to one end of the relay coil 129, and the other end of the relay coil 129 is grounded.
[0084]
Therefore, in the second relay 128, when the open / close switch 125 is closed and the ignition switch 110 is closed (turned on), the power of the power supply device 126 is applied to the relay coil 129, so that a current flows through the relay coil 129. The relay coil 129 is activated to generate a magnetic force, and the open / close switch 130 is closed.
[0085]
A contact on one side of the open / close switch 130 is connected to the power supply device 131 in the starter circuit 105, and a contact on the other side of the open / close switch 130 is connected to the starter motor 132 that is the prime mover driving means 104.
[0086]
In the prime mover start control device 101 of the first example configured as described above, the position sensor 7 detects the range position where A / T2 is set and supplies the detection signal to the CPU 5. When A / T2 is set to a range position other than the non-traveling range position of the P range position or the N range position, the CPU 5 travels based on the detection signal from the position sensor 7 when A / T2 is other than the non-traveling range position. It is determined that the position is set to the range position, and an ON signal is supplied to the base 122a of the FET transistor. As a result, the switching element 122 is cut off and the first relay 123 does not operate. Then, the opening / closing switch 125 is opened, the starting circuit 105 becomes inoperable, and even if the ignition switch 110 is turned on, the second relay 128 does not operate. Therefore, the starter motor 132 does not start and the prime mover 103 is not driven.
[0087]
When A / T2 is set to the non-traveling range position of the P range position or the N range position, the position sensor 7 detects the predetermined range position and supplies the detection signal to the CPU 5. The CPU 5 determines that A / T2 is set to the non-traveling range position based on the detection signal from the position sensor 7, and supplies an off signal to the base 122a of the FET transistor. As a result, the switching element 122 becomes conductive, a start permission signal is transmitted to the relay coil 124 via the second connection line 114, and the first relay 123 is activated. Then, the opening / closing switch 125 is closed and the starting circuit 105 is in an operable state. When the ignition switch 110 is turned on, the second relay 128 is operated and the opening / closing switch 130 is closed, so that the starter motor 132 is started and the prime mover 103 is To drive.
[0088]
  According to the prime mover start control device 101 of the first example configured as described above,A start permission signal is transmitted to the start circuit 105.The second connection line 114 for connecting the control device and the external device is different from the first connection line for connecting the control device and the external device. Connecting line 114,To supply a signal from the control device with position sensor 1 to the starting circuit 105OnlyIt can be a dedicated connection line. As a result, no signal other than the start permission signal of the starter motor 132 flows through this dedicated connection line, so that the start permission signal is quickly transmitted to the starter motor 132. As a result, the A / T2 The prime mover 103 can be driven quickly according to the range position.
  The starting circuit 105Transmit start permission signalThe second connection line 114 is not limited to one, and a plurality of the second connection lines 114 may be provided.
[0089]
Further, by using the dedicated second connection line 114 for the start permission signal of the starter motor 132, other devices such as the external device 107 fail or other lines such as the first connection line 113 are connected. Even if a failure occurs, the starter motor 132 can be reliably started without affecting the failure. Thus, even during such a failure, the prime mover 103 can be reliably driven, and the drive reliability of the prime mover 103 is improved.
[0090]
Further, the first connection line 113 different from the second connection line 114 connects the CPU 5 to a plurality of devices such as CAN 115 and 116 that respectively control the devices such as the ECM 117, the ABS 118, and the door module 119 in the vehicle. Therefore, it becomes possible to control the drive control of the prime mover 103 corresponding to the range position of A / T2 and each device in the vehicle in an integrated manner.
[0091]
Furthermore, since the second connection line 114 is a high voltage supply line that supplies a higher voltage than the first connection line 113, the second connection line 114 is excellent in durability against high voltage. can do. Therefore, by providing the second connection line 114 with excellent durability against a high voltage in this way, it is possible to reliably apply a relatively high voltage without disconnecting the second connection line. .
[0092]
Further, since the first connection line 113 is a serial communication line, a signal is input to the first connection line 113 by detecting a voltage difference between the two communication lines constituting the serial communication line. Can be judged. Therefore, even if noise enters the first connection line 113, only the voltage between the two communication lines rises, and no difference due to noise occurs in the voltage difference between the two communication lines. This erroneous determination due to noise can be prevented.
[0093]
Furthermore, since the determination signal of the A / T2 range position from the CPU 5 is input to the second connection line 114, the conduction between the starter motor 132 and the power supply device 131 of the starting circuit 105 is controlled by this determination signal. By making the power supply device 131 conductive to the starter motor 132 at the non-traveling range position of A / T2, the prime mover 103 can be reliably started.
Since the starter motor 132 can be driven only at the non-traveling range position, it is possible to prevent the vehicle from starting forward or backward by mistake when driving the drive unit 103 due to a user's shift operation mistake or the like.
[0094]
Further, the position sensor 7 is constituted by a non-contact switch comprising a permanent magnet 12 whose magnetic field is displaced by the driver's operation and a magnetic sensor 13 whose output changes due to the displacement of the magnetic field of the permanent magnet 12. The A / T2 range position can be reliably detected by a non-contact switch having a simple and compact structure and wear resistance, and can be detected by an output by a magnetic field that continuously shifts the range position.
[0095]
Further, the CPU 5 controls the A / T2 based on the vehicle state detection signal such as the vehicle running state detection signal, thereby determining the range position of the A / T2, for example, the engine speed and the throttle opening degree. Since the TCM 112 having one CPU 5 is used as the drive controller for controlling the A / T 2 based on the vehicle state detection signal such as the vehicle driving state detection signal, the number of parts can be reduced and the cost can be increased. Can be prevented. In addition, since the control device with position sensor 1 is integrated with the CPU 5 for determining the A / T2 range position and the position sensor 7, the combination of the CPU 5 and the position sensor 7 can be made compact and the wiring can be simplified. Can be.
[0096]
Furthermore, since the position sensor control device 1 is provided integrally with the A / T 2, the second connection line 114 can be shortened and the second connection line 114 is not made thicker than the first connection line 113. However, it is possible to effectively reduce the occurrence of problems such as disconnection and to reduce costs.
[0097]
Furthermore, since the second connection line 114 for connecting to the starter circuit 105 of the starter motor 132 is connected to the vehicle system connection connector 9 provided in the control device with position sensor 1, the control device with position sensor 1 In addition, it is not necessary to provide a dedicated connection port for connecting to the starter circuit 105, and the cost can be reduced.
[0098]
Further, the control device with position sensor 1 is provided with an A / T connection connector 8 for connection with A / T2 separately from the vehicle system connection connector 9 connected to the starting circuit. A / T2 can be connected by the / T connection connector 8. Thereby, the A / T connection connector 8 can be arranged regardless of the position of the starter motor 132, and the degree of freedom of arrangement of the A / T connection connector 8 can be increased.
[0099]
Furthermore, according to the prime mover start control device 101 of the first example, the conduction between the power supply device 131 of the start circuit 105 and the starter motor 132 is controlled to open and close by the relay circuit 106 different from the start circuit 105. Even if a large current for driving the starter motor 132 flows through the circuit 105, the influence of the large current on the relay circuit 106 can be prevented.
[0100]
Further, since the relay drive current is output to the relay coils 124 and 129 interposed in the relay circuit 106 by the predetermined range position determination signal of A / T2 by the CPU 5, the relay circuit 106 is set to the non-traveling range position. It can be operated reliably.
[0101]
Further, since the switching element 122 provided in the control device with position sensor 1, that is, a part of the control device with position sensor 1 is interposed in a relay circuit 106 different from the start circuit 105, it flows to the start circuit 105. The influence on the control device 1 with a position sensor due to a large current can be prevented.
[0102]
Further, since the ignition switch 110 (that is, the starter switch) is interposed in the relay circuit 106 through which a current smaller than the current of the starting circuit 105 flows, the ignition switch 110 can be a small switch for small current. Thus, the starter motor 132 can be reliably driven.
[0103]
Further, when a contact type switch is generally used for the N switch provided in the position sensor 7, the contact type switch can control contact of the contact surface due to metal powder generated by a short circuit at the contact or contact wear. Since it is very difficult, the noise signal increases and drive control of the starter motor is not only difficult, but also requires a contact for each position of the range position, so there is a limit to downsizing. Therefore, the problem of such a contact type switch can be solved by making the position sensor 7 a non-contact type sensor as in the first example.
[0104]
Further, if the position sensor 7 is a non-contact type sensor, the N switch also becomes a non-contact type switch. Therefore, the N switch cannot be interposed in the starter motor start circuit. Although there is a problem that it cannot be driven, by using the second connection line 114 as in the first example, the starter motor 132 can be driven even if the N switch is configured by a non-contact switch. .
[0105]
Furthermore, according to the A / T2 of the first example, the prime mover start control device 101 is provided, so that the prime mover 103 can be driven quickly and reliably according to the range position of A / T2, Moreover, the combined structure of the A / T 2 and the prime mover start control device 101 can be formed compactly.
[0106]
In the first example, the position sensor 7 and the CPU 5 are integrated and configured as the control device 1 with the position sensor, but the position sensor 7 and the CPU 5 can be separately provided.
[0107]
Further, the control device with position sensor 1 can be provided so as to circumscribe the A / T case, or can be provided in a valve body in the A / T case. Further, when the position sensor 7 and the CPU 5 are separately provided, the CPU 5 can be provided in the A / T valve body, and the position sensor 7 can be provided in contact with the A / T case.
[0108]
Further, in the first example described above, the position sensor 7 is constituted by a magnetic field generating means made of a permanent magnet that is a non-contact type switch. However, a non-contact sensor that detects the range position by an optical interrupter or the like can also be used. . Further, instead of the non-contact type sensor (non-contact switch), a contact type switch generally used conventionally as the position sensor 7 of A / T2 can also be used.
Further, the three power supply devices 126, 127, 131 can be constituted by one common power supply device, or at least two of these three power supply devices 126, 127, 131 can be made common. .
[0109]
FIG. 8 is a view similar to FIG. 7 schematically showing a second example of the embodiment of the prime mover start control device of the present invention. In the following description of each example, the same components as those in the previous examples are denoted by the same reference numerals, and detailed description thereof is omitted.
[0110]
In the first example described above, two relays 123 and 128 are used. However, as shown in FIG. 8, in this second example, one relay 123 of the first example is omitted and only the other relay 128 is used. ing. In the first example, the ECM 117 is disposed outside the relay circuit 106. In the second example, the ECM 117 is disposed in the relay circuit 106.
[0111]
  The power supply device 133 in the ECM 117 is connected to the switching element 122 via the second connection line 114, and is connected to one contact of the ignition switch 110 via the CPU 134 of the ECM 117. In the switching element 122 of the second example, unlike the first example, when the A / T 2 is in the non-traveling range position, the CPU 5 sends an ON determination signal to the base 1 of the switching element 122.2The switching element 122 is turned on by supplying it to 2a, and when the A / T2 is in the travel range position, the CPU 5 outputs a determination signal indicating that the base 5 of the switching element 122 is off.2By supplying to 2a, the switching element 122 is cut off. When the switching element 122 is turned on, the relay 128 can be turned on, that is, the starter motor 132 can be started.
  Therefore, the prime mover start control device 101 of the second example is a type that starts the starter motor 132 via the ECM 117.
[0112]
According to the prime mover start control device 101 of the second example configured as described above, since the starter motor 132 is started via the ECM 117, various conditions are added by the CPU 134 in the ECM 117 and the starter motor 132 is added. Can be started, and the drive control of the starter motor 132 can be controlled more finely. For example, by adding a condition for detecting the failure state of the TCM 112 and the ECM 117, it is possible to perform control such as permitting drive control of the starter motor 132 if normal.
[0113]
  In addition, when an immobilizer (an engine unstartable device) is mounted, the start permission of the starter motor 132 can be controlled in consideration of the condition of the output signal from the immobilizer.The
  Furthermore, since the relay 123 is omitted from the first example, the number of parts can be reduced and the cost can be reduced.
  Other configurations and other operational effects of the second example are substantially the same as those of the first example.
[0114]
In the first and second examples described above, at least one of the relays 123 and 128 is used. However, in the present invention, these relays 123 and 128 can be omitted. For example, as shown in FIG. 9, an ignition switch 110 and a switching element 122 are connected in series to the starting circuit 105 itself between the second connection line 114 and the power supply device 131. In this way, all of the relays 123 and 128 can be omitted, and by not using a relay, the number of parts can be reduced and the cost can be reduced. In this case, the starter motor 132 and the power supply device 131 of the starting circuit 105 are directly connected, and the connection line is constituted by the second connection line 114. A voltage is applied. However, since the second connection line 114 is used as a high voltage supply line and has excellent durability, a high voltage is reliably supplied to the second connection line 114 without disconnecting the second connection line 114. can do.
In the present invention, the second connecting line 114 is connected to the starting circuit 105 via the relay circuit 106 as described above, or directly connected to the starting circuit 105 as shown in FIG.
[0115]
In addition, an ignition switch 126 is interposed in the second connection line 114 between the switching element 122 and the power supply device 126. In this way, the relay 123 can be omitted, and only one relay 128 can be used. As described above, when the ignition switch 126 is interposed in the second connection line 114, it is necessary to supply a certain amount of high voltage to the second connection line 114, but the second connection line 114 has a high voltage. Since the supply line is used, the high voltage can be reliably applied without disconnecting the second connection line 114 in this case as well.
[0116]
Furthermore, by increasing the number of relays to 3 or more and setting the operating conditions for each relay, various conditions are added according to the number of relays as described in the second example above, and a fine starter is added. The drive control of the motor 132 can be performed.
[0117]
  Further, an N switch provided in the position sensor 7 can be interposed in series with the ignition switch 110 in the starting circuit 105. In this way, the configuration of the prime mover start control device 101 is simplified.
  As described above, in the first and second examples, the number of relays and the location of the ignition switch 110 can be freely changed.
[0118]
FIG. 10 is a block diagram similar to FIG. 1, schematically showing a third example of the embodiment of the prime mover start control device according to the present invention.
In each of the above examples, the prime mover 103 is driven by the prime mover driving means 104. However, as shown in FIG. 10, the prime mover 103 of the third example is driven by itself without depending on the prime mover driving means 104. It is. Therefore, the prime mover driving means 104 is omitted.
[0119]
Such a prime mover 103 includes an electric motor and the like, and the prime mover 103 driven by the prime mover driving means 104 as in the above-described example includes an electric motor driven by an engine or an auxiliary motor.
Other configurations and operational effects of the third example are substantially the same as those of the first example.
[Brief description of the drawings]
FIG. 1 is a block diagram schematically showing a first example of an embodiment of a prime mover start control device according to the present invention.
FIG. 2 is a diagram schematically showing a prime mover start control device used in the prime mover start control device of the first example shown in FIG. 1;
FIG. 3 is a diagram schematically showing an electrical connection structure in A / T, which is one of power trains in which the first example shown in FIG. 1 is adopted.
4 is a plan view showing a control device with a position sensor of the first example shown in FIG. 3; FIG.
5 is a cross-sectional view taken along line VV in FIG.
6 is a cross-sectional view taken along line VI-VI in FIG.
FIG. 7 is a diagram partially and schematically showing an example of a specific configuration of the prime mover start control device of the first example shown in FIG. 1;
FIG. 8 is a view similar to FIG. 7 schematically showing a second example of the embodiment of the prime mover start control device of the present invention.
FIG. 9 is a diagram schematically showing a modification of the present invention.
FIG. 10 is a block diagram similar to FIG. 1, schematically showing a third example of the embodiment of the prime mover start control device according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Control apparatus with position sensor, 2 ... Automatic transmission (A / T), 3 ... Vehicle system, 5 ... Electronic control unit (CPU), 6 ... Manual shaft, 7 ... Position sensor, 8 ... For A / T connection Connector, 9 ... Connector for vehicle system, 12 ... Permanent magnet (magnetic field generating means), 13 ... Magnetic sensor, 101 ... Motor start control device, 102 ... Drive machine, 103 ... Motor, 104 ... Motor drive means, 105 ... Start Circuit, 106 ... Relay circuit, 107 ... External device, 108 ... Power supply, 109 ... Conducting means, 110 ... Ignition switch, 112 ... Transmission control module (TCM), 113 ... First connection line, 114 ... Second connection 115, high-speed controller area network (High Speed CAN), 116 low-speed controller area network Low Speed CAN), 117 ... engine control module (ECM), 122 ... switching elements, 123 and 128 ... relay circuit, 131 ... power supply device, 132 ... Starter motor

Claims (23)

A position sensor for detecting a range position of a drive unit coupled to a prime mover driven by a prime mover drive means, and a control electrically connected to the position sensor and determining the range position based on at least a signal from the position sensor With the device,
The control device and an external device that is a plurality of devices for controlling each device in the vehicle are connected by a first connection line,
The control device and the starting circuit of the prime mover driving means are connected via a switching element by a second connection line different from the first connection line,
The first connection line is configured by a network, and the network connects the control device and the plurality of devices,
The second connection line transmits a start permission signal to the starter circuit for starting the starter circuit of the prime mover driving means based on a signal from the position sensor,
The prime mover start control device, wherein the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line. A position sensor for detecting a range position of a drive unit coupled to a prime mover driven by a prime mover drive means, and a control electrically connected to the position sensor and determining the range position based on at least a signal from the position sensor With the device,
The control device and an external device that is a plurality of devices for controlling each device in the vehicle are connected by a first connection line,
The control device and a relay circuit that controls opening and closing of the starting circuit of the motor driving means are directly connected by a second connection line different from the first connection line,
The first connection line is configured by a network, and the network connects the control device and the plurality of devices,
The second connection line is for transmitting a start permission signal to the relay circuit to enable starting of the starting circuit of the prime mover driving means based on a signal from the position sensor,
The prime mover start control device, wherein the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line . The prime mover start control device according to claim 1 or 2 , wherein the control device further controls the drive unit based on a vehicle state detection signal such as a detection signal of a running state of the vehicle. The prime mover start control device according to any one of claims 1 to 3, wherein the control device is a control device with a position sensor in which the position sensor is integrated. The control device with a position sensor has a connection port for connecting to the external device, and the starting circuit is connected to the connection port via the second connection line. The motor | power_engine start control apparatus of Claim 4 . 6. The prime mover start control device according to claim 4 or 5, wherein the control device with a position sensor is provided integrally with the drive unit. The prime mover start control device according to any one of claims 4 to 6 , wherein the control device with a position sensor has a second connection port for connection with the driving machine. A position sensor for detecting a range position of a drive unit coupled to a prime mover driven by a prime mover drive means, and a control electrically connected to the position sensor and determining the range position based on at least a signal from the position sensor With the device,
The control device and an external device that is a plurality of devices for controlling each device in the vehicle are connected by a first connection line,
The control device and the starting circuit of the prime mover driving means are connected via a switching element by a second connection line different from the first connection line,
The first connection line is configured by a network, and the network connects the control device and the plurality of devices,
The second connection line transmits a start permission signal to the starter circuit for starting the starter circuit of the prime mover driving means based on a signal from the position sensor,
The prime mover start control device, wherein the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line. A position sensor for detecting a range position of a drive unit coupled to a prime mover driven by a prime mover drive means, and a control electrically connected to the position sensor and determining the range position based on at least a signal from the position sensor With the device,
The control device and an external device that is a plurality of devices for controlling each device in the vehicle are connected by a first connection line,
The control device and the starting circuit of the prime mover driving means are connected via a relay circuit that controls opening and closing of the starting circuit with a second connection line different from the first connection line,
The first connection line is configured by a network, and the network connects the control device and the plurality of devices,
The second connection line is for transmitting a start permission signal to the relay circuit to enable starting of the starting circuit of the prime mover driving means based on a signal from the position sensor,
The prime mover start control device, wherein the second connection line is a high voltage supply line that supplies a higher voltage than the first connection line. The prime mover start control device according to claim 8 or 9 , wherein the control device further controls the drive unit based on a vehicle state detection signal such as a detection signal of a running state of the vehicle. The motor start control device according to any one of claims 8 to 10, wherein the control device is a control device with a position sensor in which the position sensor is integrated. The control device with a position sensor has a connection port for connecting to the external device, and the starting circuit is connected to the connection port via the second connection line. The prime mover start control device according to claim 11 . The prime mover start control device according to claim 11 or 12, wherein the control device with a position sensor is provided integrally with the drive device. The prime mover start control device according to any one of claims 11 to 13 , wherein the control device with a position sensor has a second connection port for connection with the driving machine. The second connection line is connected to a relay coil interposed in the relay circuit, and a relay driving current is supplied to the relay coil by a signal supplied through the second connection line. The motor start control device according to claim 2 or 9 , wherein the relay circuit is operated. The prime mover start control device according to claim 2, 9 or 15, wherein the control device is interposed in the relay circuit. The motor start control device according to any one of claims 2, 9, 15 and 16 , wherein a starter switch of an ignition switch of the motor is interposed in the relay circuit. The first connection line, the prime mover starting control apparatus according to any one of claims 1 to 17, characterized in that the vehicle state detecting signal is a signal line for transmission of the external device. The prime mover start control device according to any one of claims 1 to 18 , wherein the first connection line is a serial communication line. The range position determination signal from the control device is input to the second connection line, and the determination signal is a signal for controlling conduction of the starting circuit with the power supply device. The motor start control device according to any one of claims 1 to 19 . 21. The prime mover start control device according to claim 20, wherein the position sensor is a non-contact switch. 23. The prime mover start control device according to claim 21 , wherein the non-contact switch includes a magnetic field generating means for changing a magnetic field by a driver's operation and a sensor for changing an output by the displacement of the magnetic field. An automatic transmission comprising the prime mover start control device according to any one of claims 1 to 22 and constituting the drive unit.

Images