JP2018115758A - Vehicle control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform a control for preventing belt slippage properly using slip information.SOLUTION: When an occurence frequency of tire slip is comparatively high, belt-slippage prevention control is performed by increasing a belt nipping pressure. When the occurence frequency of the tire slip is comparatively low, the belt-slippage prevention control is performed by reducing a torque capacity of a second clutch C2. That is, an increase of the belt nipping pressure or a reduction of the torque capacity of the second clutch C2 is selectively used as the belt-slippage prevention control according to the occurence frequency of the tire slip based on a slip map MAPslp received from a center, and therefore, deterioration of fuel consumption can be restrained while prioritizing reliability (i.e., belt-slippage prevention and function-reduction prevention of the second clutch C2). Therefore, the belt-slippage prevention control can be performed properly using the slip map MAPslp.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a vehicle control device including a belt-type continuously variable transmission and a clutch provided downstream of the continuously variable transmission.

  2. Description of the Related Art A vehicle control device that receives slip information related to an area where drive wheel slip easily occurs from outside the vehicle and performs control using the slip information is well known. For example, the vehicle-mounted terminal described in Patent Document 1 is the same. In Patent Document 1, whether or not the vehicle slips at the vehicle position using the ease of slipping of the vehicle based on vehicle information such as whether or not the studless tire is mounted and the ease of slipping at the vehicle position received from the outside of the vehicle. It is disclosed to predict this.

JP 2013-206279 A

  By the way, if the rotational speed of the driving wheel during the slip is suddenly reduced, an excessive torque may be input from the driving wheel side. In a vehicle equipped with a belt-type continuously variable transmission, belt slippage of the continuously variable transmission may occur when such excessive torque is input. On the other hand, it is known to perform control to prevent belt slip by increasing the belt clamping pressure of the continuously variable transmission. For this reason, it is conceivable to perform control for preventing belt slip using slip information received from outside the vehicle. If the belt clamping pressure is increased, fuel consumption may be deteriorated. Therefore, it is desired to perform control for preventing belt slip by appropriately using slip information.

  The present invention has been made against the background of the above circumstances, and an object of the present invention is to provide a vehicle control device capable of performing control for preventing belt slip by appropriately utilizing slip information. There is.

  The subject matter of the first invention is (a) a belt-type continuously variable transmission that transmits power from a power source to driving wheels, and a power transmission path between the continuously variable transmission and the driving wheels. And (b) receiving slip information relating to an area where slippage of the drive wheels is likely to occur from an external device different from the vehicle, (c) ) When the region where the vehicle frequently travels is a region where the slip is likely to occur and the current position of the vehicle is within the region where the slip is likely to occur, the belt of the continuously variable transmission While performing control to prevent belt slip of the continuously variable transmission by increasing the clamping pressure, (d) the region where the vehicle is frequently traveling is not the region where the slip is likely to occur, or the vehicle The current position of the slip occurs Easily if is outside the region is to perform control for preventing belt slip of the continuously variable transmission by reducing the torque capacity of the clutch.

  According to the first aspect of the present invention, when the frequency of occurrence of slipping of the drive wheels is relatively high, control is performed to prevent belt slippage by increasing the belt clamping pressure, so that the torque capacity of the clutch is reduced. Accordingly, it is possible to prevent a decrease in durability of the friction material due to sliding of the clutch. On the other hand, when the frequency of slipping of the drive wheels is relatively low, control is performed to prevent belt slip by reducing the torque capacity of the clutch, so the durability of the friction material is reduced by sliding the clutch It is possible to prevent fuel consumption from deteriorating. In other words, depending on the slip occurrence frequency based on the slip information received from the vehicle exterior device, the belt clamping pressure is increased or the clutch torque capacity is selectively reduced as control for preventing belt slipping. It is possible to suppress deterioration in fuel consumption while giving priority to the performance (that is, prevention of belt slippage and reduction in clutch function). Therefore, it is possible to perform control for preventing belt slip by appropriately using slip information.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining the schematic structure of the vehicle to which this invention is applied, and is a figure explaining the principal part of the control function and various control systems for various control in a vehicle. It is a flowchart explaining the control operation | movement for performing the belt slip prevention control appropriately using the principal part of the control operation | movement of an electronic controller, ie, a slip map.

  In an embodiment of the present invention, the continuously variable transmission includes, for example, a fixed sheave, a movable sheave, and a hydraulic actuator that applies a thrust for changing a groove width between the fixed sheave and the movable sheave. Pulley (also referred to as a primary pulley) and an output side pulley (also referred to as a secondary pulley), and a transmission belt wound around the primary pulley and the secondary pulley. The vehicle includes a hydraulic pressure control circuit that independently controls a working hydraulic pressure (pulley hydraulic pressure) supplied to the hydraulic actuator. The hydraulic control circuit may be configured to generate pulley hydraulic pressure as a result by controlling the flow rate of hydraulic oil to the hydraulic actuator, for example. By such a hydraulic control circuit, each thrust (= pulley hydraulic pressure × pressure receiving area) in the primary pulley and the secondary pulley is controlled, so that the target shift can be realized while preventing the transmission belt from slipping. At this time, the shift control is executed. The transmission belt is an endless annular compression transmission belt having an endless annular hoop and a plurality of thick plate-like blocks (elements) connected in the thickness direction along the hoop, or alternately stacked. For example, a tension type transmission belt constituting an endless annular link chain in which end portions of the formed link plates are connected to each other by connecting pins. In a broad sense, the concept of a belt-type continuously variable transmission includes a chain-type continuously variable transmission.

  The power source is, for example, an engine such as a gasoline engine or a diesel engine that generates power by burning fuel. Further, the vehicle may include an electric motor or the like as a power source in addition to or instead of the engine.

  The vehicle exterior device is a center that collects the slip occurrence information associated with the vehicle position information and sets the slip information. The vehicle exterior device includes another vehicle, and the vehicle receives the slip information from the other vehicle when the vehicle cannot receive the slip information from the center.

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

  FIG. 1 is a diagram illustrating a schematic configuration of a vehicle 10 to which the present invention is applied, and also illustrates a control function for various controls in the vehicle 10 and a main part of a control system. In FIG. 1, a vehicle 10 includes an engine 12 that functions as a power source, drive wheels 14, and a power transmission device 16 provided in a power transmission path between the engine 12 and the drive wheels 14. The power transmission device 16 is connected to a known torque converter 20 as a fluid transmission device connected to the engine 12, an input shaft 22 connected to the torque converter 20, and an input shaft 22 in a case 18 as a non-rotating member. The belt type continuously variable transmission 24, the forward / reverse switching device 26 connected to the input shaft 22, and connected to the input shaft 22 via the forward / backward switching device 26 and provided in parallel with the continuously variable transmission 24. A pair of gear transmission mechanism 28, continuously variable transmission 24, and output shaft 30, which is a common output rotation member of gear transmission mechanism 28, counter shaft 32, output shaft 30 and counter shaft 32 are provided so as to be relatively non-rotatable and mesh with each other. A reduction gear device 34 composed of the above-mentioned gear, a gear 36 provided in a counter-rotatable manner on the counter shaft 32, a differential gear 38 connected to the gear 36, and the like. The power transmission device 16 includes left and right axles 40 connected to the differential gear 38. In the power transmission device 16 configured as described above, the power output from the engine 12 (the torque and the force are synonymous unless otherwise distinguished) is transmitted to the torque converter 20, the continuously variable transmission 24 (or the forward / reverse switching device 26 and the like). Gear transmission mechanism 28), reduction gear device 34, differential gear 38, axle 40, etc. are sequentially transmitted to left and right drive wheels 14.

  As described above, the power transmission device 16 includes the gear transmission mechanism 28 and the continuously variable transmission 24 provided in parallel with the power transmission path PT between the engine 12 and the drive wheels 14. Therefore, the power transmission device 16 continuously variable shifts the power of the engine 12 from the input shaft 22 and the first power transmission path PT1 for transmitting the power of the engine 12 from the input shaft 22 to the drive wheels 14 via the gear transmission mechanism 28. A plurality of power transmission paths, which are the second power transmission path PT <b> 2 that is transmitted to the drive wheels 14 via the machine 24, are provided in parallel between the input shaft 22 and the output shaft 30. The power transmission device 16 is switched between the first power transmission path PT1 and the second power transmission path PT2 in accordance with the traveling state of the vehicle 10. Therefore, the power transmission device 16 includes a plurality of engagement devices that selectively switch the power transmission path for transmitting the power of the engine 12 to the drive wheels 14 between the first power transmission path PT1 and the second power transmission path PT2. I have. The engagement device connects and disconnects the first power transmission path PT1 (in other words, the first power transmission path PT1 is formed by being engaged), and the first clutch C1 (the first brake B1 at the time of reverse travel); And a second clutch C2 that connects and disconnects the second power transmission path PT2 (in other words, forms the second power transmission path PT2 by being engaged). The first clutch C1, the first brake B1, and the second clutch C2 are all known hydraulic friction engagement devices that are frictionally engaged by a hydraulic actuator. Further, each of the first clutch C1 and the first brake B1 is one of the elements constituting the forward / reverse switching device 26, as will be described later.

  The engine 12 includes an engine control device 42 having various devices necessary for output control of the engine 12, such as an electronic throttle device, a fuel injection device, and an ignition device. The engine 12 is controlled by an electronic control unit 90 described later in accordance with an operation amount (accelerator operation amount) θacc of an accelerator pedal corresponding to a drive request amount for the vehicle 10 by a driver. Torque Te is controlled.

  The torque converter 20 includes a pump impeller 20 p connected to the engine 12 and a turbine impeller 20 t connected to the input shaft 22. The power transmission device 16 includes a mechanical oil pump 44 connected to the pump impeller 20p. The oil pump 44 is rotationally driven by the engine 12 to control the transmission of the continuously variable transmission 24, generate belt clamping pressure in the continuously variable transmission 24, and operate each of the plurality of engagement devices. The original pressure of the working hydraulic pressure for switching the state (the state such as engagement or disengagement) is supplied to the hydraulic control circuit 46 provided in the vehicle 10.

  The forward / reverse switching device 26 includes a double pinion type planetary gear device 26p, a first clutch C1, and a first brake B1. The carrier 26c of the planetary gear device 26p is connected to the input shaft 22, the ring gear 26r of the planetary gear device 26p is selectively connected to the case 18 via the first brake B1, and the sun gear 26s is connected to the input shaft 22 around the input shaft 22. 22 is connected to a small-diameter gear 48 that is coaxially rotatable with respect to the shaft 22. The carrier 26c and the sun gear 26s are selectively connected via the first clutch C1.

  The gear transmission mechanism 28 is provided with a small-diameter gear 48, a gear mechanism counter shaft 50, and a gear mechanism counter shaft 50 that is provided around the gear mechanism counter shaft 50 so as not to rotate relative to the gear mechanism counter shaft 50. And a radial gear 52. The gear transmission mechanism 28 includes an idler gear 54 provided around the gear mechanism countershaft 50 so as to be rotatable relative to the gear mechanism countershaft 50, and an output shaft 30 around the output shaft 30. An output gear 56 is provided on the coaxial center so as not to rotate relative to the idler gear 54. The output gear 56 has a larger diameter than the idler gear 54. Therefore, the gear transmission mechanism 28 forms one gear stage in the power transmission path PT between the input shaft 22 and the output shaft 30. The gear transmission mechanism 28 further includes a meshing clutch D1 that is provided between the large-diameter gear 52 and the idler gear 54 around the gear mechanism counter shaft 50, and selectively connects and disconnects between these gears. The meshing clutch D1 is an engagement device that connects and disconnects the first power transmission path PT1 (in other words, the first power transmission path PT1 is formed by being engaged with the first clutch C1). Included in the combined device. The operating state of the meshing clutch D <b> 1 is switched by the operation of the hydraulic actuator 58 provided in the power transmission device 16.

  The first power transmission path PT1 is formed by engaging the meshing clutch D1 and the first clutch C1 (or the first brake B1) provided closer to the input shaft 22 than the meshing clutch D1. . A forward power transmission path is formed by the engagement of the first clutch C1, and a reverse power transmission path is formed by the engagement of the first brake B1. In the power transmission device 16, when the first power transmission path PT <b> 1 is formed, the power transmission state in which the power of the engine 12 can be transmitted from the input shaft 22 to the output shaft 30 via the gear transmission mechanism 28 is set. The On the other hand, the first power transmission path PT1 has a neutral state (power) in which power transmission is interrupted when at least the first clutch C1 and the first brake B1 are both released or at least the meshing clutch D1 is released. Transmission interruption state).

  The continuously variable transmission 24 includes a primary pulley 60 having a variable effective diameter connected to the input shaft 22, a rotary shaft 62 provided coaxially with the output shaft 30, and a variable effective diameter connected to the rotary shaft 62. Secondary pulley 64 and a transmission belt 66 as a transmission element wound between the pulleys 60 and 64, and a frictional force (clamping pressure) between the pulleys 60 and 64 and the transmission belt 66. Power transmission via the belt clamping pressure), and the power of the engine 12 is transmitted to the drive wheel 14 side.

  The primary pulley 60 includes a fixed sheave 60a coupled to the input shaft 22, and a movable sheave 60b provided so as not to rotate relative to the fixed sheave 60a around the axis of the input shaft 22 and to move in the axial direction. And a hydraulic actuator 60c that applies a primary thrust Win (= primary pressure Pin × pressure receiving area) in the primary pulley 60 for changing the V groove width between the sheaves 60a and 60b. The secondary pulley 64 includes a fixed sheave 64a coupled to the rotary shaft 62, and a movable sheave 64b provided so as not to be rotatable relative to the fixed sheave 64a around the axis of the rotary shaft 62 and to be movable in the axial direction. And a hydraulic actuator 64c that applies secondary thrust Wout (= secondary pressure Pout × pressure receiving area) in the secondary pulley 64 for changing the V groove width between the sheaves 64a and 64b. The primary pressure Pin is a hydraulic pressure supplied to the hydraulic actuator 60 c by the hydraulic control circuit 46, and the secondary pressure Pout is a hydraulic pressure supplied to the hydraulic actuator 64 c by the hydraulic control circuit 46. The hydraulic pressures Pin and Pout are pulley hydraulic pressures that apply thrusts Win and Wout that press the movable sheaves 60b and 64b toward the fixed sheaves 60a and 64a, respectively.

  In the continuously variable transmission 24, the primary thrust Pin and the secondary thrust Wout are respectively controlled by adjusting the primary pressure Pin and the secondary pressure Pout by a hydraulic control circuit 46 driven by an electronic control unit 90 described later. The As a result, the V groove width of each of the pulleys 60 and 64 is changed, the engagement diameter (effective diameter) of the transmission belt 66 is changed, and the gear ratio γcvt (= primary pulley rotation speed Npri / secondary pulley rotation speed Nsec) is changed. In addition, the frictional force between the pulleys 60 and 64 and the transmission belt 66 (that is, the belt clamping pressure) is controlled so that the transmission belt 66 does not slip. That is, the primary speed Pin (primary thrust Win is also agreed) and the secondary pressure Pout (secondary thrust Wout is also agreed) are controlled so that the transmission belt 66 is prevented from slipping (also referred to as belt slip) and the actual gear ratio γcvt. Is the target gear ratio γcvtt. The belt clamping pressure is a belt torque capacity Tcvt that is a torque capacity of the transmission belt 66 in the continuously variable transmission 24.

  In the continuously variable transmission 24, for example, when the primary pressure Pin is increased, the V groove width of the primary pulley 60 is narrowed to reduce the speed ratio γcvt, that is, the continuously variable transmission 24 is upshifted. Further, when the primary pressure Pin is lowered, the V groove width of the primary pulley 60 is widened to increase the gear ratio γcvt, that is, the continuously variable transmission 24 is downshifted. In the continuously variable transmission 24, the belt speed is prevented by the primary pressure Pin and the secondary pressure Pout, and the target speed ratio γcvtt is realized by the mutual relationship between the primary thrust Win and the secondary thrust Wout. The target gear shift is not realized only with one pulley hydraulic pressure (thus agreeing with thrust).

  The output shaft 30 is disposed around the rotation shaft 62 so as to be relatively rotatable coaxially with the rotation shaft 62. The second clutch C2 is a clutch provided in a power transmission path between the continuously variable transmission 24 and the drive wheels 14 (here, the output shaft 30 also agrees). The second power transmission path PT2 is formed by engaging the second clutch C2. In the power transmission device 16, when the second power transmission path PT <b> 2 is formed, a power transmission possible state in which the power of the engine 12 can be transmitted from the input shaft 22 to the output shaft 30 via the continuously variable transmission 24. Is done. On the other hand, the second power transmission path PT2 is set to the neutral state when the second clutch C2 is released.

  Further, the vehicle 10 includes a transceiver 68. The transmitter / receiver 68 is a device that communicates with a center 100 (also referred to as a center 100) that is present separately from the vehicle 10 and is an external device different from the vehicle 10. An electronic control unit 90 to be described later transmits / receives various information to / from the center 100 via the transmitter / receiver 68. The center 100 has a function as a server, and receives, processes, stores, and provides various information. Similarly to the vehicle 10, the center 100 transmits and receives various types of information to and from other vehicles 110 a, 110 b,. The other vehicle 110 basically has the same function as the vehicle 10.

  Further, the vehicle 10 includes an electronic control device 90 as a controller including a control device for the vehicle 10 related to control of the engine 12, the continuously variable transmission 24, and the like. The electronic control unit 90 includes, for example, a so-called microcomputer having a CPU, a RAM, a ROM, an input / output interface, and the like. The CPU uses a temporary storage function of the RAM and follows a program stored in the ROM in advance. Various controls of the vehicle 10 are executed by performing signal processing. The electronic control unit 90 controls the output of the engine 12, the hydraulic control related to the shift control of the continuously variable transmission 24 and the belt clamping pressure control, and the operating states of each of the plurality of engagement devices (C1, B1, C2, D1). It performs hydraulic control related to switching, and is configured separately for engine control and hydraulic control as required.

  The electronic control device 90 includes various sensors provided in the vehicle 10 (for example, various rotational speed sensors 70, 72, 74, 76, an accelerator operation amount sensor 78, a throttle opening sensor 80, a shift position sensor 82, a GPS antenna, etc. (For example, engine rotation speed Ne, primary pulley rotation speed Npri which is the rotation speed of the input shaft 22, secondary pulley rotation speed Nsec which is the rotation speed of the rotation shaft 62, etc.) Output shaft rotation speed Nout corresponding to the vehicle speed V, accelerator operation amount θacc indicating the magnitude of the driver's acceleration operation, throttle opening tap, operation position POSsh of the shift lever 86 provided in the vehicle 10, GPS signal, etc. The position information Svp of the vehicle 10 on the surface of the earth or the map, etc.) is supplied respectively. Further, the electronic control device 90 sends various command signals (for example, an engine control command signal Se for controlling the engine 12) to each device (for example, the engine control device 42, the hydraulic control circuit 46, etc.) provided in the vehicle 10. Hydraulic control command signal Sccvt for hydraulic control related to gear shifting of the stepped transmission 24, belt clamping pressure, etc., and hydraulic control related to switching of the operating states of the plurality of engagement devices (C1, B1, C2, D1). Hydraulic control command signal Scbd and the like are output.

  The electronic control unit 90 includes an engine control unit, that is, an engine control unit 92, and a hydraulic control unit, that is, a hydraulic control unit 94 in order to realize various controls in the vehicle 10.

  The engine control unit 92 controls the engine control device 42 so that the requested engine torque Te is obtained. For example, the engine control unit 92 applies the accelerator operation amount θacc and the vehicle speed V to a relationship (for example, a driving force map) obtained and stored experimentally or design in advance (that is, a predetermined driving force map). The required drive torque Tdem is calculated. The engine control unit 92 outputs an engine control command signal Se for controlling the engine 12 so as to obtain an engine torque Te that realizes the required drive torque Tdem.

  When the hydraulic control unit 94 forms the power transmission path in the power transmission device 16 by the first power transmission path PT1, the hydraulic control command signal Scbd for engaging the meshing clutch D1 by the hydraulic actuator 58, the first clutch The hydraulic control command signal Scbd for engaging C1 (or the first brake B1 at the time of reverse travel) and the hydraulic control command signal Scbd for releasing the second clutch C2 are output to the hydraulic control circuit 46. On the other hand, when the hydraulic control unit 94 forms the power transmission path in the power transmission device 16 by the second power transmission path PT2, the hydraulic control command signal Scbd for releasing the first clutch C1 and the first brake B1; And a hydraulic control command signal Scbd for engaging the second clutch C <b> 2 is output to the hydraulic control circuit 46.

  The hydraulic pressure control unit 94 achieves the target speed ratio γcvtt of the continuously variable transmission 24 while preventing belt slippage of the continuously variable transmission 24 when traveling while forming the second power transmission path PT2. In addition, the speed ratio γcvt and belt torque capacity Tcvt (that is, belt clamping pressure) of the continuously variable transmission 24 are controlled. Specifically, the hydraulic control unit 94 applies the accelerator operation amount θacc and the vehicle speed V to a predetermined relationship (for example, a shift map, a belt clamping pressure map (belt torque capacity map)), thereby continuously variable transmission. The primary pressure Pin and the secondary pressure for achieving the target speed ratio γcvtt of the continuously variable transmission 24 in which the operating point of the engine 12 is on a predetermined optimum line (for example, the engine optimum fuel consumption line) while preventing the belt slippage of 24. Each hydraulic pressure command (hydraulic control command signal Scvt) of the pressure Pout is determined, and each of these hydraulic pressure commands is output to the hydraulic pressure control circuit 46.

  Here, during the travel in which the second power transmission path PT2 is formed, if the slip of the drive wheel 14 (also referred to as tire slip) occurs, and then the rotational speed of the drive wheel 14 is rapidly reduced, the drive wheel 14 side If an excessive torque is input from, and the excessive torque is transmitted to the continuously variable transmission 24, belt slip may occur. On the other hand, control for preventing belt slip by increasing the belt clamping pressure of the continuously variable transmission 24 in preparation for excessive torque input during tire slip (also referred to as belt slip prevention control or belt protection control). ). Alternatively, during tire slip, in preparation for the input of excessive torque, the torque capacity of the second clutch C2 is reduced so that when the excessive torque is actually input, the second clutch C2 is slid (that is, the second clutch). It is conceivable to perform belt slip prevention control by operating C2 as a torque limiter. In addition, as a situation where excessive torque is input from the drive wheel 14 side, for example, the drive wheel 14 slips during driving on a rough road such as a wavy road, and then the rotation speed of the drive wheel 14 is increased by gripping. When the driving wheel 14 slips rapidly when traveling on a low μ road, and the rotational speed of the driving wheel 14 suddenly decreases due to exiting the low μ road during the slip, or a low μ road It is assumed that the rotational speed of the drive wheels 14 has suddenly decreased due to a sudden braking operation performed by the driver during traveling.

  By the way, in the belt slip prevention control for increasing the belt clamping pressure, there is a possibility that the fuel consumption is deteriorated. On the other hand, in the belt slip prevention control for reducing the torque capacity of the second clutch C2, sliding the second clutch C2 may cause a decrease in the durability of the friction material in the second clutch C2. As the number of times of sliding increases, the function of the second clutch C2 is likely to deteriorate. For this reason, in this embodiment, when the occurrence frequency of tire slip is relatively high, in order to avoid an increase in the number of times the second clutch C2 is slid, the belt clamping pressure is increased. The belt slip prevention control is executed. On the other hand, when the occurrence frequency of tire slip is relatively low, belt slip prevention control for reducing the torque capacity of the second clutch C2 is executed in order to prevent or suppress deterioration in fuel consumption.

  In the present embodiment, information on an area where tire slip has occurred in the vehicle 10 or the other vehicle 110 is collected, slip information on an area where tire slip is likely to occur is set based on the information, and the slip information received from outside the vehicle. The belt slip prevention control corresponding to the occurrence frequency of the tire slip is executed by appropriately using. This slip information is, for example, a map in which an area where tire slip is likely to occur is set, and is referred to as a slip map MAPslp.

  Specifically, the electronic control unit 90 further includes a vehicle state determination unit, that is, a vehicle state determination unit 96, an information processing unit, that is, an information processing unit 98, and a belt slip, in order to realize the belt slip prevention control as described above. Prevention control means, that is, a belt slip prevention control unit 99 is provided.

  The vehicle state determination unit 96 determines whether tire slip has occurred. For example, the vehicle state determination unit 96 reliably determines that the output shaft angular acceleration dNout / dt corresponding to the angular acceleration of the drive wheel 14 that is the changing speed of the output shaft rotational speed Nout is slipping. It is determined whether or not tire slip has occurred based on whether or not a predetermined slip determination threshold is exceeded.

  When the vehicle state determination unit 96 determines that the tire slip has occurred, the information processing unit 98 associates the information that the tire slip has occurred with the position information Svp of the vehicle 10 when the tire slip has occurred. Thus, the control information Ic is generated. The information processing unit 98 transfers this control information Ic to the center 100 via the transceiver 68.

  Control information Ic similar to that of the vehicle 10 is transferred from the other vehicle 110 to the center 100. The center 100 sets an area where tire slip is likely to occur based on the information that the tire slip has occurred in the control information Ic and the position information Svp. For example, when the center 100 has an occurrence frequency of the tire slip (for example, the number of occurrences or the occurrence rate in a certain period) in a predetermined area surrounding the point where the tire slip occurs in the control information Ic, the center 100 exceeds the predetermined frequency. The area is set to an area where tire slip is likely to occur. This predetermined range is a predetermined range that is considered appropriate to be set as an area where tire slip is likely to occur, for example. The predetermined frequency is a predetermined lower limit frequency for determining that the region is prone to tire slip. The center 100 has a slip map MAPslp, and when a region where tire slip is likely to occur is newly set, the center 100 updates the slip map MAPslp to reflect the new setting. Thus, the center 100 collects tire slip occurrence information associated with the position information Svp and sets the slip map MAPslp. The center 100 periodically determines whether the occurrence frequency of tire slip exceeds a predetermined frequency in an area that has already been set as an area where tire slip is likely to occur, and the occurrence frequency of tire slip is equal to or less than the predetermined frequency. If it is, the region is set outside the region where tire slip is likely to occur, and the slip map MAPslp is updated to reflect the new setting.

  The information processing unit 98 receives the slip map MAPslp of the center 100 from the center 100 via the transceiver 68 as necessary after the vehicle 10 is turned on, for example, when the ignition is turned on.

  The vehicle state determination unit 96 uses the slip map MAPslp to determine whether or not the region where the vehicle 10 travels frequently is a region where tire slip is likely to occur (that is, the region where the occurrence frequency of tire slip exceeds a predetermined frequency). Determine whether. A region where the vehicle 10 is frequently traveled is a region where the user mainly uses the vehicle 10. For example, the region where the vehicle 10 is located the longest in a certain period (predetermined period) among the regions divided by a certain range (predetermined range) is the travel frequency of the vehicle 10. It is stored by the electronic control unit 90 as a high area.

  The vehicle state determination unit 96 uses the slip map MAPslp to determine whether the current position of the vehicle 10 based on the position information Svp is within an area where tire slip is likely to occur.

  The belt slip prevention control unit 99 determines that an area where the vehicle 10 is frequently traveled is an area where tire slip is likely to occur, and the current position of the vehicle 10 causes tire slip. When it is determined that the vehicle is in an easy area, that is, when the occurrence frequency of tire slip is relatively high and the vehicle state determination unit 96 determines that tire slip has occurred. Then, a command for executing belt clamping pressure up control for increasing the pulley hydraulic pressure by a predetermined pressure so as to increase the belt clamping pressure is output to the hydraulic control unit 94 to perform belt slip prevention control. The normal pulley hydraulic pressure is a value determined by the hydraulic pressure control unit 94 based on the belt clamping pressure map, for example. The predetermined pressure is, for example, a predetermined lower limit value that needs to increase the pulley hydraulic pressure so that belt slip does not occur with respect to an assumed excessive torque input.

  On the other hand, the belt slip prevention control unit 99 is the time when the vehicle state determination unit 96 determines that the region where the vehicle 10 frequently travels is not an area where tire slip is likely to occur, or the current state of the vehicle 10 When it is determined that the position is outside the region where tire slip is likely to occur, that is, when the frequency of occurrence of tire slip is relatively low, tire slip has occurred by the vehicle state determination unit 96 If it is determined, the hydraulic control unit 94 issues a command to execute clutch C2 pressure down control for reducing the clutch hydraulic pressure supplied to the second clutch C2 to a predetermined slip pressure so as to reduce the torque capacity of the second clutch C2. To prevent belt slippage. From the viewpoint of preventing the belt slip of the continuously variable transmission 24 by sliding the second clutch C2 in response to an input of excessive torque, the predetermined slip pressure is, for example, at least the torque capacity of the second clutch C2 is a continuously variable transmission. The clutch hydraulic pressure is smaller than 24 belt torque capacity Tcvt.

  As described above, the belt slip prevention control unit 99 uses the slip map MAPslp to determine that the region where the vehicle 10 frequently travels is an area where tire slip is likely to occur and the current position of the vehicle 10 is tire slip. If the belt is in an area where it is likely to occur, belt slip prevention control is performed by increasing the belt clamping pressure of the continuously variable transmission 24. On the other hand, the belt slip prevention control unit 99 uses the slip map MAPslp when the region where the vehicle 10 is frequently traveled is not an area where tire slip is likely to occur or when the current position of the vehicle 10 causes tire slip. When it is outside the area where it is easy, belt slip prevention control is performed by reducing the torque capacity of the second clutch C2.

  FIG. 2 is a flowchart for explaining the control operation of the electronic control device 90, that is, the control operation for performing the belt slip prevention control appropriately using the slip map MAPslp. For example, the control operation is repeatedly executed after the vehicle 10 is turned on. Is done.

  In FIG. 2, first, a slip map MAPslp is received from the center 100 via the transmitter / receiver 68 in a step (hereinafter, step is omitted) S <b> 10 corresponding to the function of the information processing unit 98 as necessary. Next, in S20 corresponding to the function of the vehicle state determination unit 96, using the slip map MAPslp, an area where the vehicle 10 is frequently traveled is an area where tire slip is likely to occur (that is, the occurrence frequency of tire slip exceeds a predetermined frequency). It is determined whether or not the current area is). If the determination in S20 is affirmative, in S30 corresponding to the function of the vehicle state determination unit 96, using the slip map MAPslp, it is determined whether or not the current position of the vehicle 10 is within an area where tire slip is likely to occur. Determined. If the determination in S30 is affirmative, it is determined in S40 corresponding to the function of the vehicle state determination unit 96 whether tire slip has occurred. If the determination at S40 is negative, this routine is terminated. If the determination in S40 is affirmative, in S50 corresponding to the function of the belt slip prevention control unit 99, belt slip prevention control is executed by belt clamping pressure up control. On the other hand, if the determination in S20 is negative, or if the determination in S30 is negative, it is determined in S60 corresponding to the function of the vehicle state determination unit 96 whether tire slip has occurred. Is done. If the determination at S60 is negative, this routine is terminated. If the determination in S60 is affirmative, in S70 corresponding to the function of the belt slip prevention control unit 99, belt slip prevention control is executed by clutch C2 pressure down control.

  As described above, according to the present embodiment, when the occurrence frequency of tire slip is relatively high, the belt slip prevention control is performed by increasing the belt clamping pressure. By reducing the torque capacity, it is possible to prevent a decrease in the durability of the friction material caused by sliding the second clutch C2. On the other hand, when the occurrence frequency of tire slip is relatively low, the belt slip prevention control is performed by reducing the torque capacity of the second clutch C2, and therefore friction caused by sliding the second clutch C2 is performed. It is possible to prevent deterioration in fuel consumption while suppressing a decrease in durability of the material. That is, depending on the occurrence frequency of tire slip based on the slip map MAPslp received from the center 100, the belt slip prevention control is selectively used to increase the belt clamping pressure or decrease the torque capacity of the second clutch C2. Therefore, deterioration of fuel consumption can be suppressed while giving priority to reliability (that is, prevention of belt slippage and prevention of functional degradation of the second clutch C2). Therefore, the belt slip prevention control can be performed by appropriately using the slip map MAPslp.

  As mentioned above, although the Example of this invention was described in detail based on drawing, this invention is applied also in another aspect.

  For example, in the above-described embodiment, the belt slip prevention control is executed using the slip map MAPslp received from the center 100. There may be a case where the vehicle 10 cannot receive the slip map MAPslp from the center 100 for some reason. In such a case, the slip map MAPslp may be received from the other vehicle 110 that has the slip map MAPslp received from the center. In this case, the external device different from the vehicle 10 includes the other vehicle 110 in addition to the center 100. The transceiver 68 is also a device that communicates with the other vehicle 110.

  In the above-described embodiment, the slip map MAPslp is used to determine whether or not the region where the vehicle 10 travels frequently is an area where tire slip is likely to occur, and the current position of the vehicle 10 is an area where tire slip is likely to occur. The vehicle 10 determines whether or not the vehicle is in the vehicle, but is not limited to this mode. For example, such a determination may be performed at the center 100. In such a case, slip information relating to an area where tire slip is likely to occur becomes this determination result, and this determination result is received by the vehicle 10 and used for execution of belt slip prevention control. Therefore, in such a case, for example, the determination result is received in S10 of FIG. 2, and in S20 and S30, whether or not the occurrence frequency of tire slip is relatively high is determined based on the determination results. Determined. Alternatively, the center 100 has the slip map MAPslp and updates the slip map MAPslp, but the present invention is not limited to this mode. For example, the center 100 may have only the function of collecting the control information Ic from the vehicle 10 and the other vehicle 110. In such a case, slip information relating to an area where tire slip is likely to occur is the control information Ic, and the control information Ic is received by the vehicle 10, and an area where tire slip is likely to occur using the control information Ic. The belt slip prevention control is executed based on the setting. As described above, the execution by the vehicle 10 and the execution by the center 100 may be executed by any one except that it can be executed by only one of the vehicle 10 and the center 100. .

  In the above-described embodiment, the belt slip prevention control is executed after the occurrence of tire slip, but this is not a limitation. For example, the belt slip prevention control by the belt clamping pressure up control may be executed in advance before the occurrence of the tire slip when it is determined that the occurrence frequency of the tire slip is relatively high.

  In the above-described embodiment, it is determined whether or not a tire slip has occurred based on the output shaft angular acceleration dNout / dt, but this is not a limitation. For example, it may be determined whether or not tire slip has occurred based on the change speed of the wheel speed of the drive wheel 14. Alternatively, the wheel speed of the drive wheel 14 (the higher of the wheel speeds of the left and right drive wheels or the average value of the wheel speeds of the left and right drive wheels) is the average value of the wheel speeds of the left and right driven wheels. It may be determined that a tire slip has occurred when it is higher than a predetermined threshold.

  In the above-described embodiment, the vehicle 10 has a plurality of power transmission paths including a first power transmission path PT1 via the gear transmission mechanism 28 and a second power transmission path PT2 via the continuously variable transmission 24. Although it provided in parallel between the input shaft 22 and the output shaft 30, it is not restricted to this aspect. For example, the vehicle 10 may only include a power transmission path via the continuously variable transmission 24 between the input shaft 22 and the output shaft 30. In short, a vehicle having a belt-type continuously variable transmission that transmits power from a power source to driving wheels, and a clutch provided in a power transmission path between the continuously variable transmission and the driving wheels. If present, the present invention can be applied.

  The above description is only an embodiment, and the present invention can be implemented in variously modified and improved forms based on the knowledge of those skilled in the art.

10: Vehicle 12: Engine (power source)
14: Drive wheel 24: Continuously variable transmission 90: Electronic control device (control device)
100: Center (external device)
C2: Second clutch (clutch)

Claims (1)

A control device for a vehicle, comprising: a belt-type continuously variable transmission that transmits power from a power source to driving wheels; and a clutch provided in a power transmission path between the continuously variable transmission and the driving wheels. Because
Slip information related to an area where the slip of the driving wheel is likely to occur is received from an external device different from the vehicle,
When the region where the vehicle frequently travels is a region where the slip is likely to occur, and the current position of the vehicle is within the region where the slip is likely to occur, the belt of the continuously variable transmission is While performing control to prevent belt slippage of the continuously variable transmission by increasing the pressure,
When the area where the vehicle is frequently driven is not an area where the slip is likely to occur, or when the current position of the vehicle is outside the area where the slip is likely to occur, the torque capacity of the clutch is reduced. A control apparatus for a vehicle, wherein control for preventing belt slippage of the continuously variable transmission is performed.

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