Patent Description:
As a conventional hybrid vehicle, one described in <CIT> is known. The hybrid vehicle described in <CIT> includes a manual transmission which is connected to an engine through a clutch, a motor which is provided in an output shaft of the manual transmission, and a clutch releasing means for automatically obtaining a disengaged state of the clutch even when a clutch pedal is not depressed. This clutch releasing means is configured as a hydraulic device including an oil reservoir, an oil pump, a pressure regulating valve, a linear solenoid valve, and the like and applies a hydraulic pressure to the clutch which is engaged by a clutch spring to disengage the clutch.

According to the hybrid vehicle described in <CIT>, since the clutch releasing means disengages the clutch at least when the manual transmission is in a non-neutral state in a motor running state using the motor, it is possible to prevent the engine from dragging in the motor running state and to efficiently operate the motor.

However, in the hybrid vehicle described in <CIT>, since the clutch releasing means configured as the hydraulic device including a plurality of components is provided to prevent the engine from dragging in the EV running state (motor running state), there are problems in which the structure becomes complicated and the manufacturing cost increases.

This invention has been made in view of the above-described circumstances and an object of this invention is to provide a hybrid vehicle capable of preventing an engine from dragging in an EV running state without complicating a structure of a hybrid vehicle in which an engine and a manual transmission are connected through a clutch operated by a driver.

Some optional features are defined by the dependent claims.

In this way, according to this invention, it is possible to provide a hybrid vehicle capable of preventing an engine drag in an EV running state without complicating a structure of a hybrid vehicle in which an engine and a manual transmission are connected through a clutch operated by a driver and to easily switch a running state using an engine and a running state using a motor.

A hybrid vehicle according to embodiments of this invention includes: an engine; a clutch operated by a driver; a manual transmission receiving power transmitted from the engine through the clutch; and a drive wheel receiving power transmitted from the manual transmission, wherein the manual transmission includes an input shaft receiving power input from the engine, a counter shaft disposed in parallel to the input shaft, and a plurality of gear pairs changing a rotation speed of the input shaft and transmitting the rotation speed to the counter shaft, wherein a motor generator is connected to a power transmission path between the counter shaft and the drive wheel so that driving power is able to be transmitted, and wherein a one-way clutch transmitting power in one direction from the input shaft to the counter shaft is provided in one gear of a specific gear pair of the plurality of gear pairs. Accordingly, the hybrid vehicle according to embodiments of this invention can prevent the engine from dragging in an EV running state without complicating the structure of the hybrid vehicle in which the engine and the manual transmission are connected through the clutch operated by the driver and to easily switch the running state using the engine and the running state using the motor.

Hereinafter, a hybrid vehicle according to embodiments of this invention will be described with reference to the drawings.

<FIG> and <FIG> are diagrams showing a hybrid vehicle according to embodiments of this invention.

First, a configuration will be described. In <FIG>, a hybrid vehicle <NUM> includes an engine <NUM> (denoted as ENG in the figure), a clutch <NUM> which is operated by a driver, a manual transmission <NUM> to which power is transmitted from the engine <NUM> through the clutch <NUM>, and a drive wheel <NUM> to which power is transmitted from the manual transmission <NUM>. Further, the hybrid vehicle <NUM> includes a motor generator <NUM> (denoted as MG in the figure) which generates running power.

The engine <NUM> is an internal combustion engine which generates running power (engine torque) by using a gasoline or diesel fuel. The clutch <NUM> is provided between a crankshaft 2A of the engine <NUM> and an input shaft <NUM> of the manual transmission <NUM> and all the power of the engine <NUM> transmitted to the manual transmission <NUM> is transmitted through this clutch <NUM>. The clutch <NUM> is switched between an engaged state in which power is transmitted between the crankshaft 2A and the input shaft <NUM> and an open state (disengaged state) in which power is not transmitted. The clutch <NUM> is mechanically connected to a clutch pedal <NUM> through a connecting mechanism 9B and the engaged state and the open state are switched in accordance with the movement of the clutch pedal <NUM>. That is, the clutch <NUM> is opened only when the driver depresses the clutch pedal <NUM> (clutch operation).

The manual transmission <NUM> is a parallel shaft gear type transmission that is manually operated to shift to any one of a forward gear stage of a first speed stage to a fifth speed stage and a backward gear stage.

The manual transmission <NUM> includes the input shaft <NUM> to which power of the engine <NUM> is input, a counter shaft <NUM> which is disposed in parallel to the input shaft <NUM>, and a plurality of gear pairs 10A to 10F which change the rotation speed of the input shaft <NUM> and transmit the rotation speed to the counter shaft <NUM>. The input shaft <NUM> is connected to the engine <NUM> through the clutch <NUM>.

The input shaft <NUM> is provided with a first-speed stage input gear 11A, a second-speed stage input gear 11B, a third-speed stage input gear 11C, a fourth-speed stage input gear 11D, a fifth-speed stage input gear 11E, and an input gear 11F for a backward gear stage.

The input gears 11A and 11B are fixed to the input shaft <NUM> and rotate together with the input shaft <NUM>. The input gears 11C, 11D, 11E, and 11F are relatively rotatably supported by the input shaft <NUM> through a needle bearing (not shown).

The counter shaft <NUM> is provided with a first-speed stage counter gear 12A, a second-speed stage counter gear 12B, a third-speed stage counter gear 12C, a fourth-speed stage counter gear 12D, a fifth-speed stage counter gear 12E, a counter gear 12F for a backward gear stage, and a final drive gear <NUM> for a forward gear stage.

The counter gears 12A, 12B, 12C, 12D, and 12E always mesh with the input gears 11A, 11B, 11C, 11D, and 11E constituting the same gear stage. For example, the fourth-speed stage counter gear 12D always meshes with the fourth-speed stage input gear 11D. The counter gear 12F for a backward gear stage always meshes with an idler gear <NUM> always meshing with the input gear 11F for a backward gear stage.

The input gear 11A and the counter gear 12A constitute the first-speed stage gear pair 10A and the input gear 11B and the counter gear 12B constitute the second-speed stage gear pair 10B. The input gear 11C and the counter gear 12C constitute the third-speed stage gear pair 10C and the input gear 11D and the counter gear 12D constitute the fourth-speed stage gear pair 10D. The input gear 11E and the counter gear 12E constitute the fifth-speed stage gear pair 10E and the input gear 11F and the counter gear 12F constitute the gear pair 10F for a backward gear stage.

The counter gears 12A and 12B are relatively rotatably supported by the counter shaft <NUM> through a needle bearing (not shown). The counter gears 12C, 12D, 12E, and 12F and the final drive gear <NUM> are fixed to the counter shaft <NUM> and rotate together with the counter shaft <NUM>.

In this embodiment, the fifth speed stage is the forward gear stage with the smallest reduction ratio and is the highest speed stage also called as a top gear. The gear pair 10E constituting the fifth speed stage is a specific gear pair in the plurality of gear pairs 10A to 10F. A one-way clutch <NUM> is provided in the input gear 11E which is one gear of the gear pair 10E constituting the fifth speed stage and is provided in the input shaft <NUM>.

The one-way clutch <NUM> is provided between the outer peripheral portion (the tooth portion) of the input gear 11E and the inner peripheral portion (the connection portion to the input shaft <NUM>). Specifically, the input gear 11E is divided into the outer peripheral portion side always meshing with the counter gear 12E and the inner peripheral portion side connected to the input shaft <NUM> at a synchronizer <NUM> to be described later and the one-way clutch <NUM> is provided therebetween.

The one-way clutch <NUM> rotates the outer peripheral portion of the input gear 11E together with the inner peripheral portion of the input gear 11E when the rotation speed of the inner peripheral portion of the input gear 11E is about to be equal to or larger than the rotation speed of the outer peripheral portion of the input gear 11E and conversely allows the rotation speed of the outer peripheral portion of the input gear 11E to be equal to or larger than the rotation speed of the inner peripheral portion of the input gear 11E. That is, when the rotation speed of the input shaft <NUM> is smaller than the rotation speed of the tooth portion of the input gear 11E, the tooth portion of the input gear 11E is relatively rotated (idly rotated) with respect to the input shaft <NUM>. Thus, the one-way clutch <NUM> transmits power from the input shaft <NUM> to the counter shaft <NUM> in a direction in which the rotation speed of the counter shaft <NUM> increases and transmits power from the counter shaft <NUM> to the input shaft <NUM> in a direction in which the rotation speed of the input shaft <NUM> decreases. Additionally, the magnitude of the rotation speed mentioned here is the rotation speed in which the direction in which the vehicle rotates when moving forward is positive.

A synchronizer <NUM> for switching a first speed stage and a second speed stage is provided between the counter gear 12A and the counter gear 12B of the counter shaft <NUM>. A synchronizer <NUM> for switching a third speed stage and a fourth speed stage is provided between the input gear 11C and the input gear 11D of the input shaft <NUM>. A synchronizer <NUM> for switching a fifth speed stage and a backward gear stage is provided between the input gear 11E and the input gear 11F of the input shaft <NUM>. A shift lever <NUM> is mechanically connected to the synchronizers <NUM>, <NUM>, and <NUM> of the manual transmission <NUM> through a connecting mechanism (not shown).

When shifting to the first speed stage, the synchronizer <NUM> connects the first-speed stage counter gear 12A to the counter shaft <NUM>. Accordingly, the counter gear 12A rotates together with the counter shaft <NUM> and the power of the engine <NUM> is transmitted from the input shaft <NUM> to the counter shaft <NUM> through the input gear 11A and the counter gear 12A.

When shifting to the second speed stage, the synchronizer <NUM> connects the second-speed stage counter gear 12B to the counter shaft <NUM>. Accordingly, the counter gear 12B rotates together with the counter shaft <NUM> and the power of the engine <NUM> is transmitted from the input shaft <NUM> to the counter shaft <NUM> through the input gear 11B and the counter gear 12B.

When shifting to the third speed stage, the synchronizer <NUM> connects the input gear 11C to the input shaft <NUM>. Accordingly, the input gear 11C rotates together with the input shaft <NUM> and the power of the engine <NUM> is transmitted from the input shaft <NUM> to the counter shaft <NUM> through the input gear 11C and the counter gear 12C.

When shifting to the fourth speed stage, the synchronizer <NUM> connects the input gear 11D to the input shaft <NUM>. Accordingly, the input gear 11D rotates together with the input shaft <NUM> and the power of the engine <NUM> is transmitted from the input shaft <NUM> to the counter shaft <NUM> through the input gear 11D and the counter gear 12D.

When shifting to the fifth speed stage, the synchronizer <NUM> connects the inner peripheral portion of the input gear 11E to the input shaft <NUM>. Accordingly, the inner peripheral portion of the input gear 11E rotates together with the input shaft <NUM> and the power of the engine <NUM> is transmitted from the input shaft <NUM> to the inner peripheral portion of the input gear 11E. Then, the one-way clutch <NUM> rotates the outer peripheral portion of the input gear 11E together with the inner peripheral portion of the input gear 11E and the one-way clutch <NUM> transmits the positive driving power of the engine <NUM> to the counter shaft <NUM> through the counter gear 12E. Additionally, since the outer peripheral portion of the input gear 11E rotates at a lower speed than the input shaft <NUM> and the one-way clutch <NUM> works so that the rotation speed of the inner peripheral portion of the input gear 11E is not equal to or larger than the same rotation speed as the outer peripheral portion of the input gear 11E at a speed other than the fifth speed stage (highest speed stage) during running, the shift operation to the fifth speed stage can synchronize and connect the input shaft <NUM> and the inner peripheral portion of the input gear 11E without any problem even when the rotation speed of the clutch disc is high.

Further, in the shift operation to the fifth speed stage when the rotation speed of the clutch disc is low, the synchronization can be performed without any problem only by connecting the inner peripheral portion of the input gear 11E, which is separated from the outer peripheral portion of the input gear 11E by the function of the one-way clutch <NUM>, to the input shaft <NUM>.

When shifting to the backward gear stage, the synchronizer <NUM> connects the input gear 11F to the input shaft <NUM>. Accordingly, the power of the engine <NUM> is transmitted from the input shaft <NUM> to the counter shaft <NUM> through the input gear 11F, the idler gear <NUM>, and the counter gear 12F.

The hybrid vehicle <NUM> includes a differential device <NUM> and a ring gear 5A of the differential device <NUM> meshes with the final drive gear <NUM> of the manual transmission <NUM>. The differential device <NUM> transmits the power output from the manual transmission <NUM> to left and right drive wheels <NUM> through a drive shaft <NUM> to be differentially rotatable.

The hybrid vehicle <NUM> includes a motor generator <NUM> (denoted as MG in the figure) and this motor generator <NUM> generates running power (motor torque) by using electric power of a battery (not shown).

An output gear 8B is fixed to an output shaft 8A of the motor generator <NUM> and the output gear 8B meshes with the ring gear 5A of the differential device <NUM>. Thus, the motor generator <NUM> is always connected to a power transmission path between the counter shaft <NUM> and the drive wheel <NUM> so that power can be input and output. That is, power generated by the motor generator <NUM> is transmitted to the drive wheel <NUM> through the differential device <NUM> and the drive shaft <NUM> without using the input shaft <NUM>. In contrast, power from the drive wheel <NUM> is transmitted to the motor generator <NUM> through the drive shaft <NUM> and the differential device <NUM>.

The motor generator <NUM> can also regeneratively generate power using kinetic energy transmitted from the drive wheel <NUM> when the hybrid vehicle <NUM> decelerates. Thus, the motor generator <NUM> is a rotating electrical machine having both functions of a motor and a generator.

In this way, the motor generator <NUM> is always connected to the power transmission path between the counter shaft <NUM> and the drive wheel <NUM> so that power can be input and output. Additionally, the motor generator <NUM> may be provided in the power transmission path between the counter shaft <NUM> and the drive wheel <NUM> and, for example, the counter shaft <NUM> may be rotated by the motor generator <NUM> so that the output gear 8B of the motor generator <NUM> meshes with the final drive gear <NUM> of the counter shaft <NUM>.

The hybrid vehicle <NUM> includes a control unit <NUM>. The control unit <NUM> is configured as a computer unit including a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory storing backup data or the like, an input port, and an output port. The ROM of the computer unit stores a program for allowing the computer unit to function together with various constants or various maps.

A top gear detection sensor 17A is connected to the input port of the control unit <NUM>. The top gear detection sensor 17A is provided in the shift lever <NUM>, detects that the shift lever <NUM> is in the fifth speed stage as the top gear, and outputs a detection signal to the control unit <NUM>.

A clutch sensor 9A is connected to the input port of the control unit <NUM>. The clutch sensor 9A is provided in the clutch pedal <NUM>, detects a clutch operation (depressing the clutch pedal <NUM>), and outputs a detection signal to the control unit <NUM>. A notification unit <NUM> configured as a speaker or a display screen (not shown) is connected to the output port of the control unit <NUM>.

The control unit <NUM> is configured to switch the running mode of the hybrid vehicle <NUM>. The running modes of the hybrid vehicle <NUM> include an EV mode and an HEV mode.

The EV mode is a running mode that stops the operation of the engine <NUM> and drives the hybrid vehicle <NUM> by the power of the motor generator <NUM>. In the EV mode, the control unit <NUM> controls the motor generator <NUM> so that a driver request torque is satisfied by the power of the motor generator <NUM>.

The HEV mode is a running mode that operates the engine <NUM> and drives the hybrid vehicle <NUM> by the power of the engine <NUM> and the power of the motor generator <NUM>. In the HEV mode, the control unit <NUM> controls the engine <NUM> and the motor generator <NUM> so that a driver request torque is satisfied by the power of the engine <NUM> and the power of the motor generator <NUM>.

The control unit <NUM> switches to the EV mode when a predetermined EV mode transition condition is established in the HEV mode. The EV mode transition condition consists of the following three conditions (<NUM>), (<NUM>), and (<NUM>), and is established when all these three conditions are satisfied.

When the EV mode transition condition is not established in the EV mode, that is, at least one of the above three conditions (<NUM>), (<NUM>), and (<NUM>) is not satisfied, the control unit <NUM> starts the engine <NUM> and switches to the HEV mode.

When a predetermined EV mode transition condition including a shift operation to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM> is established in the HEV mode, the control unit <NUM> stops the operation of the engine <NUM> and switches to the EV mode.

Further, if all the EV mode transition conditions are established when shifting to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM>, the control unit <NUM> notifies the driver by the notification unit <NUM> that the shifting to the EV mode is possible when shifting to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM>. Hereinafter, the state of the vehicle when this notification is made will be described as the "EV mode transition condition is temporarily established.

That is, the control unit <NUM> determines that the EV mode transition condition is temporarily established when (<NUM>) and (<NUM>) of the above (<NUM>), (<NUM>), and (<NUM>) included in the EV mode transition condition are satisfied, but (<NUM>) is not satisfied (when the state is established if the above (<NUM>) is satisfied) and notifies the driver that the shifting to the EV mode is possible when (<NUM>) is satisfied.

Further, when the clutch <NUM> is operated in the EV mode, the control unit <NUM> starts the engine <NUM> and switches to the HEV mode. For example, when the driver depresses the clutch <NUM> to switch from the fifth speed stage to the fourth speed stage in the EV mode, the control unit <NUM> starts the engine <NUM> in advance at the timing when the clutch <NUM> is operated and completes the starting of the engine by the timing when the shifting to the fourth speed stage and the operation of the clutch <NUM> are finished. Similarly, when the state of charge of the battery becomes smaller than a specified value or when the accelerator pedal is depressed to be a specified value or more, the control unit <NUM> starts the engine <NUM> and shifts to the HEV mode.

A running mode switching operation by the control unit <NUM> will be described with reference to <FIG>. This running mode switching operation is repeatedly performed at a predetermined interval.

As shown in <FIG>, the control unit <NUM> allows the hybrid vehicle <NUM> to run in the HEV mode (step S1) and then determines whether or not the EV mode transition condition is temporarily established (step S2). The EV mode transition condition is temporarily established when the above (<NUM>) and (<NUM>) of the above three conditions constituting the EV mode transition condition are satisfied, but (<NUM>) is not satisfied.

That is, when the state of charge of the battery is equal to or larger than a specified value and the driver request torque can be satisfied by the motor torque, but the gear stage of the manual transmission <NUM> is not operated to the fifth speed stage, the EV mode transition condition is temporarily established.

When the EV mode transition condition is not temporarily established in step S2, the control unit <NUM> returns to step S1.

When it is determined that the EV mode transition condition is temporarily established in step S2, the control unit <NUM> notifies the driver that the vehicle can shift to the EV mode by the notification unit <NUM> (step S3).

Next, the control unit <NUM> determines whether or not the EV mode transition condition is established (step S4).

When the EV mode transition condition is not established in step S4, the control unit <NUM> returns to step S1.

Here, when the driver operates the gear stage of the manual transmission <NUM> to the highest speed stage and releases the depression of the clutch pedal <NUM>, the condition (<NUM>) is satisfied and the EV mode transition condition is established. When it is determined that the EV mode transition condition is established in step S4, the control unit <NUM> stops the operation of the engine <NUM> and switches to the EV mode (step S5). In this way, the control unit <NUM> automatically switches the running mode to the EV mode when the EV mode transition condition is established. Further, at this time, it is possible to stop the engine <NUM> without operating the clutch <NUM> by relatively rotating the inner peripheral portion of the input gear 11E with respect to the outer peripheral portion of the input gear 11E by the action of the one-way clutch <NUM>.

The control unit <NUM> determines whether or not the engine start condition is established after switching to the EV mode in step S5 (step S6). Here, the control unit <NUM> determines that the engine start condition is established when the EV mode transition condition is not established. When the engine start condition is not established in step S6, the control unit <NUM> returns to step S5 and continues the EV mode.

When it is determined that the engine start condition is established in step S6, the control unit <NUM> starts the engine <NUM> to switch to the HEV mode (step S7) and ends the current operation.

The starting of the engine <NUM> in step S7 is performed when a fuel is supplied to the engine <NUM> and a starter (not shown) provided in the engine <NUM> is driven to rotate the crankshaft 2A.

In the hybrid vehicle <NUM> configured as described above, when the gear stage is any of the first speed stage to the fourth speed stage or the backward gear stage, the running mode is set to the HEV mode by the control unit <NUM> and the vehicle runs by the power of the engine <NUM> and the power of the motor generator <NUM>. Further, in the hybrid vehicle <NUM>, when the gear stage is the fifth speed stage, the running mode is set to the EV mode by the control unit <NUM> and the vehicle runs by the power of the motor generator <NUM>.

As the engine brake of the hybrid vehicle <NUM>, at least one of the actual engine brake of the engine <NUM> and the brake obtained by the regenerative power generation of the motor generator <NUM> can be used in the HEV mode and the brake obtained by the regenerative power generation of the motor generator <NUM> can be used in the EV mode.

Additionally, the forward gear stage of the manual transmission <NUM> is not limited to five speeds of the first speed stage to the fifth speed stage and may be the sixth speed stage or the like. Further, the one-way clutch <NUM> may be also provided in another gear stage instead of the fifth speed stage as the top gear. For example, the one-way clutch <NUM> may be provided in one gear of the gear pairs 10A, 10B, and 10C of the first speed stage, the second speed stage, and the third speed stage. In this way, the hybrid vehicle <NUM> can be started by the power of the motor generator <NUM>.

As described above, according to the hybrid vehicle <NUM> of this embodiment, the motor generator <NUM> is connected to the power transmission path between the counter shaft <NUM> and the drive wheel <NUM> so that the driving power can be transmitted and the one-way clutch <NUM> which transmits power in one direction from the input shaft <NUM> to the counter shaft <NUM> is provided in the input gear 11E which is one gear of the specific gear pair 10E of the plurality of gear pairs 10A to 10F.

Accordingly, when the vehicle runs in the EV running state by stopping the operation of the engine <NUM> when the manual transmission <NUM> is located at the fifth speed stage corresponding to the specific gear pair 10E, it is possible to cut off the transmission of the power from the counter shaft <NUM> to the input shaft <NUM> and to prevent the engine <NUM> from dragging by the idle rotation of the one-way clutch <NUM>. The dragging of the engine <NUM> means that the crankshaft 2A of the stopped engine <NUM> is rotated by the rotation of the motor generator or the like through the manual transmission <NUM> in the EV running state. Here, since it is necessary to add a clutch actuator configured as a hydraulic device or the like, a clutch stroke sensor detecting a depression amount (clutch stroke) of the clutch pedal <NUM>, a shift position sensor detecting a current gear stage, and a clutch pedal load emulator simulating a reaction force when the clutch pedal <NUM> is depressed to the manual transmission <NUM> when the clutch <NUM> is released by a clutch actuator or the like in order to prevent the engine <NUM> from dragging in the EV running state, the structure becomes complicated. On the other hand, according to this embodiment, it is possible to eliminate the need for a clutch actuator or the like for releasing the clutch <NUM> and hence to prevent the complication of the structure.

As a result, it is possible to prevent the engine <NUM> from dragging in the EV running state without complicating the structure in the hybrid vehicle <NUM> in which the engine <NUM> and the manual transmission <NUM> are connected through the manually operated clutch <NUM>.

Further, according to the hybrid vehicle <NUM> of this embodiment, the one-way clutch <NUM> is provided in the input gear 11E which is one gear of the gear pair 10E constituting the fifth speed stage which is the forward gear stage with the smallest reduction ratio in the plurality of gear pairs 10A to 10F.

Accordingly, since the top gear detection sensor 17A can be configured as a simple and inexpensive switch or the like capable of detecting that the shift lever <NUM> is in the fifth speed stage as the top gear, it is possible to reduce the manufacturing cost. Further, since it is possible to suppress the engine <NUM> from being operated with low efficiency such as when cruising at a constant vehicle speed in a low load state and to allow the vehicle to run by the motor generator <NUM> which is more efficient than the engine <NUM> in a low load state, it is possible to improve fuel efficiency. Further, since it is possible to perform the EV running operation in which the engine <NUM> is stopped at the fifth speed stage which is the top gear used for cruising for a long time, it is possible to perform quiet cruising without engine noise.

Further, according to the hybrid vehicle <NUM> of this embodiment, the one-way clutch <NUM> is provided in the input gear 11E which is one gear of the gear pair 10E and provided in the input shaft <NUM>.

Accordingly, since the input gear 11E of the input gear 11E and the counter gear 12E constituting the gear pair 10E has a large diameter, it is easy to ensure a space for adding the one-way clutch <NUM>. Accordingly, it is possible to dispose the one-way clutch <NUM> with sufficient torque capacity without changing the reduction ratio of the gear pair 10E or the distance between the input shaft <NUM> and the counter shaft <NUM> by increasing the size of the input gear 11E. Further, since it is not necessary to rotate the outer peripheral portion of the input gear 11E which has a large diameter and inertial weight together with the input shaft <NUM> when starting the engine <NUM> by operating a starter while engaging the clutch <NUM> in order to switch to the HEV running state, the counter shaft <NUM> is not rotated anymore and hence the engine <NUM> can be smoothly started.

Further, according to the hybrid vehicle <NUM> of this embodiment, the control unit <NUM> is provided to switch the HEV mode allowing the vehicle to run by the power of the engine <NUM> and the power of the motor generator <NUM> and the EV mode allowing the vehicle to run by the power of the motor generator <NUM> and the control unit <NUM> switches to the EV mode by stopping the engine <NUM> when a predetermined EV mode transition condition including a shift operation to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM> is established in the HEV mode.

Accordingly, it is possible to eliminate the need for the driver to switch to the EV mode and to automatically switch to the EV mode when the EV mode transition condition is established.

Further, according to the hybrid vehicle <NUM> of this embodiment, when the EV mode transition condition is established by the shift operation to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM>, the control unit <NUM> notifies the driver by the notification unit <NUM> that the shifting to the EV mode is possible when shifting to the gear pair 10E constituting the fifth speed stage and provided with the one-way clutch <NUM>.

Accordingly, for example, when the EV mode transition condition is established by the shift operation to the fifth speed stage, it is possible to prompt the driver to shift to the EV mode by performing the shift operation to the fifth speed stage.

Further, according to the hybrid vehicle <NUM> of this embodiment, the control unit <NUM> starts the engine <NUM> and switches to the HEV mode when the clutch <NUM> is operated in the EV mode.

Accordingly, since it is possible to start the engine <NUM> at the timing when the clutch operation associated with the shift operation is performed when the driver shifts the fifth speed stage to another speed stage, it is possible to complete the transition to the HEV mode until the shift operation and the clutch operation end.

Claim 1:
A hybrid vehicle (<NUM>) comprising:
an engine (<NUM>);
a motor generator (<NUM>);
a clutch (<NUM>) operated by a driver;
a manual transmission (<NUM>) receiving power transmitted from the engine (<NUM>) through the clutch (<NUM>); and
a drive wheel (<NUM>) receiving power transmitted from the manual transmission (<NUM>),
wherein the manual transmission (<NUM>) includes an input shaft (<NUM>) receiving power input from the engine (<NUM>), a counter shaft (<NUM>) disposed in parallel to the input shaft (<NUM>), a one-way clutch (<NUM>), and a plurality of gear pairs (10A-10F) changing a rotation speed of the input shaft (<NUM>) and transmitting the rotation speed to the counter shaft (<NUM>),
wherein the motor generator (<NUM>) is connected to a power transmission path between the counter shaft (<NUM>) and the drive wheel (<NUM>) so that driving power is able to be transmitted, and
the one-way clutch (<NUM>) is provided in one gear of a specific gear pair of the plurality of gear pairs (10A-10F) and configured to prohibit the one gear (11E) from being driven by the counter shaft (<NUM>) but to allow the one gear (11E) to drive the counter shaft (<NUM>) in one rotational direction,
wherein the specific gear pair constitutes a forward gear stage with the smallest reduction ratio of the plurality of gear pairs (10A-10F),
the hybrid vehicle further comprising:
a control unit (<NUM>) switching an HEV mode allowing a running operation by the power of the engine (<NUM>) and the power of the motor generator (<NUM>) and an EV mode allowing a running operation by the power of the motor generator (<NUM>), the hybrid vehicle being characterized in that:
when a predetermined EV mode transition condition, including a shift operation for shifting to the forward gear stage with the smallest reduction ratio, is established in the HEV mode, the control unit (<NUM>) stops the engine (<NUM>) and switches to the EV mode.