KR20200081573A - Shifting gear device for vehicle - Google Patents

Abstract

The present invention relates to a technology for preventing erroneous operation of a shift lever by simplifying the structure of a transmission mechanism while forming one shift stage on the same shift gate. According to the present invention, introduced is a transmission mechanism for a vehicle comprising: a finger which is operated by selecting and shifting, and having a fork-shaped finger fork portion opposite to the shifting operation direction; an interlock plate which is moved along with the finger in the selecting operation direction, and has a fork-shaped interlock fork portion formed on both sides of the finger fork portion opposite to the shifting operation direction; and a jaw member having one end fixed to a shift rail, having the other end located at a position in which the finger fork portion and the interlock fork portion face each other, and the position of the other end changed to another position in which the finger fork portion and the interlock fork portion face each other according to the selection movement of the finger.

Description

SHIFTTING GEAR DEVICE FOR VEHICLE}

The present invention relates to a transmission mechanism for a vehicle that simplifies the structure of the transmission mechanism while forming a single transmission stage on the same transmission gate to prevent misoperation of the transmission lever, while reducing costs through component simplification.

The multi-stage transmission used for large-sized freight vehicles is composed of a splitter stage, a main stage, and a range stage. The splitter and the range are operated by pneumatics of the air cylinder by operating a switch provided on the shift lever, and the main stage is a shifting cable. The shift is made by the operation of.

FIG. 1 illustrates a shift gate pattern of a conventional multi-stage transmission, and is a structure called a single-H pattern in which a low range section and a high range section are overlapped.

In this, the SINGLE-H pattern is required to prevent the operator's shift lever misoperation by forming two shift stages on the same shift gate, and for this purpose, the valve body composed of several solenoid valves and pneumatic valves is configured to malfunction. Prevention system is implemented.

However, the parts required to implement the erroneous operation prevention system are expensive, and there are a number of failure factors of the system, and thus there is a problem in that the system is mounted and maintained, which is expensive.

The matters described as the above background technology are only for improving understanding of the background of the present invention, and should not be taken as an admission that it corresponds to the prior art already known to those skilled in the art.

KR 10-2016-0079452 A

The present invention has been devised to solve the problems as described above, while forming a single shift stage on the same shift gate to simplify the structure of the shift mechanism to prevent misoperation of the shift lever, while reducing the cost through component simplification. It is to provide a transmission gear for a vehicle that saves.

The configuration of the present invention for achieving the above object is moved in the axial direction, the selection operation is performed, the shaft is rotated about a shifting operation, and a fork-shaped finger fork portion is formed opposite the shifting operation direction; The fingers are moved in the selecting operation direction, and on both sides of the finger fork portion, a fork-shaped interlock fork portion is formed opposite the shifting operation direction, and the interlock groove portion of the interlock fork portion faces the finger protrusion of the finger fork portion, An interlock plate arranged such that the interlock protrusion of the interlock fork portion faces the finger groove portion of the finger fork portion; And a plurality of provided, one end is fixed to the shift rail, the other end is located on any part of the finger fork portion and the interlock fork portion, the position of the other end facing the finger fork portion and the interlock fork portion according to the selection movement of the finger The jaw member to be changed to a different position; including, the shifting of the shift rail in the axial direction as the other end of any one jaw member facing the finger protrusion moves into the interlock groove part facing the finger protrusion It can be characterized by letting.

A control shaft provided with a shifting actuation force; further provided, and the finger is coupled to the control shaft; A select lug groove may be formed on a part of the outer surface of the finger to provide a selecting actuation force to the finger through the select lug groove.

A finger is inserted into the shape surrounding a part of the outer circumferential surface of the control shaft; Both ends of the interlock plate may be inserted into the control shaft to be supported at both ends of the finger.

The finger fork portion is formed by continuously connecting the finger protrusion and the finger groove along the axial direction of the outer peripheral surface of the finger; The interlock fork portion is formed by continuously connecting the interlock protrusion and the interlock groove between both ends of the interlock plate, and is provided at a position facing the finger fork portion; The interlock fork portion may be provided on each side of the finger fork portion.

The axial direction of the shift rail is arranged in a direction orthogonal to the axial direction of the finger; One end of the jaw member is inserted and coupled to the shift rail; At the other end of the jaw member, a fork-shaped shift lug portion is formed to face the selecting operation direction, and a shift lug groove portion in the center of the shift lug portion is formed in an open shape in a select operation direction, so that the finger fork portion is the shift lug. It can be moved in the direction of the selecting operation within the groove.

The jaw member comprises a first jaw member and a second jaw member coupled to different shift rails, and when the other end of the first jaw member is located between the finger protrusion and the interlock groove, the second jaw The other end of the member is configured to be located between the finger groove portion and the interlock protrusion; When the other end of the first jaw member is located between the finger groove portion and the interlock protrusion, the other end of the second jaw member may be configured to be located between the finger protrusion and the interlock groove.

A widthwise length of the finger protrusion formed in the center of the finger fork portion is formed to form a selection operation interval of two stages; The length of the width of the finger groove and the finger protrusion leading to both sides of the central finger protrusion is formed to form a selection operation interval in one step; A widthwise length of the interlock groove formed in the center of the interlock fork portion corresponding to the central finger protrusion is formed to form a selection operation interval of two stages; The width of the interlock protrusions and the interlock grooves leading to both sides of the center interlock groove is formed to form a selection operation interval in one step; The width of the first jaw member and the other end of the second jaw member may be formed to form a selection operation interval in one step.

The length in the width direction between the other end of the first jaw member and the other end of the second jaw member may be arranged at three stages of the selection operation interval.

Through the above-described problem solving means, the present invention implements to form a single shift stage on the same shift gate while mechanically preventing an interlock phenomenon in which two shift stage gears are engaged at the same time, thereby preventing an existing malfunction operation system. It is possible to remove expensive parts necessary for realization, thereby simplifying the structure of the transmission mechanism, thereby reducing the cost of the vehicle.

1 is a view showing an existing shift pattern.
2 is a view showing an example of a DOUBLE-H shift pattern according to the present invention.
Figure 3 is a view showing the overall configuration of a transmission mechanism according to the present invention.
Figure 4 is an enlarged view showing a configuration in which a finger, an interlock plate, and a jaw member according to the present invention are combined.
5 is a view showing a structure in which the jaw member is located under the finger according to the present invention.
6 is a view showing a finger, an interlock plate, and a first jaw member and a second jaw member separately according to the present invention.
7 is a view illustrating an example of a position change and shiftable shift stage of a finger and an interlock plate according to a selecting operation in a low range according to the present invention.
Figure 8 is a view showing an example of the position change and shiftable shift stage of the finger and the interlock plate according to the selecting operation in the high range according to the present invention.

If described in detail by the accompanying drawings, preferred embodiments of the present invention.

The transmission mechanism for a vehicle of the present invention is configured to include a finger 10, an interlock plate 20 and a jaw member 30, and is preferably a manual of a large cargo vehicle having a splitter stage, a main stage, and a range stage. It may be applicable to a transmission, or may be applied to an automated manual transmission vehicle having a manual transmission mechanism.

In addition, it is applicable to the DOUBLE-H shifting pattern as shown in FIG. 2, and a structure in which a low range and a high range are switched through a selection operation of the shift lever.

Referring to Figures 3, 4 and 6, looking at the present invention in detail, the finger 10 is moved in the axial direction to be selected and operated, rotated about the axis to be shifted, and the shifting direction The fork-shaped finger fork portion 11 is formed to face.

The interlock plate 20 is moved along with the finger 10 in the selecting operation direction, and fork-shaped interlock fork portions 21 are formed on both sides of the finger fork portion 11 opposite the shifting operation direction. However, the interlock groove portion 21a of the interlock fork portion 21 faces the finger protrusion portion 11a of the finger fork portion 11, and the interlock protrusion portion 21b of the interlock fork portion 21 is a finger fork portion ( It is arranged to face the finger groove portion (11b) of 11).

The jaw member 30 is provided with a plurality, one end is fixed to the shift rail 40, the other end is located in any part facing the finger fork portion 11 and the interlock fork portion 21, the finger 10 ) Has a structure in which the position of the other end is changed to another position facing the finger fork portion 11 and the interlock fork portion 21 according to the selection movement of.

In addition, according to the shifting operation of the finger 10, the other end of any one jaw member 30 facing the finger protrusion 11a among the plurality of jaw members 30 is moved into the interlock groove 21a facing this. The shift rail 40 is shifted in the axial direction.

That is, when a selection operation is performed to shift from the current shift stage to the target shift stage, while the selecting operation force is provided to the finger 10, the interlock plate 20 together with the finger 10 axis of the finger 10 The axial position of the finger fork portion 11 and the interlock fork portion 21 is also changed along with the selection movement in the direction.

In this state, when the shifting operation is performed, the finger 10 is rotated in the corresponding shifting operation direction while the shifting operation force is provided to the finger 10, and thus faces the finger protrusion 11a of the finger 10 The jaw member 30 is pushed so that the jaw member 30 enters and moves into the interlock groove 21a.

Therefore, the shift rail 40 coupled with the jaw member 30 is moved along its axial direction, so that the gear of the corresponding shift stage can be fastened.

However, in the state where the other end of the jaw member 30 faces the finger groove part 11b, the jaw member 30 passes through the finger groove part 11b even if the finger 10 is shifted and rotated. The jaw member 30 cannot be pushed out, thereby preventing shifting operation through the jaw member 30.

Even if a part of the finger groove portion 11b is caught by the jaw member 30 and the jaw member 30 is pushed, the interlock protrusion 21b faces the shifting direction of the jaw member 30 and faces the jaw member By blocking the movement of 30, shifting operation through the jaw member 30 is prevented.

Therefore, while implementing to form one shift stage on the same shift gate and mechanically preventing the interlock phenomenon in which the two shift stage gears are engaged at the same time, it removes expensive components necessary to implement the existing malfunction prevention system. It is possible to simplify the structure of the transmission mechanism, thereby reducing the cost of the vehicle.

In addition, as shown in FIG. 3, the present invention is further provided with a control shaft 1 that provides shifting actuation force, and a finger 10 is coupled to the control shaft 1. At this time, the end of the control shaft 1 is provided with a power shift mechanism 2, it is possible to provide the shifting operation force doubled.

In addition, a select lug groove 12 is formed on a part of the outer surface of the finger 10, and a component such as a select lever is inserted into the select lug groove 12, and the finger 10 is inserted through the select lug groove 12. ).

That is, it is possible to provide the selecting operation force to the finger 10 according to the selecting operation of the shift lever, and also to provide the shifting operation force to the finger 10 according to the shifting operation of the shift lever.

And, as shown in Figure 4, the middle of the control shaft 1, the finger 10 is inserted into the shape surrounding a part of the outer peripheral surface.

In addition, both ends of the interlock plate 20 are bent vertically with respect to the interlock fork portion 21, and the bent both ends are inserted into the control shaft 1, thereby bending the interlock plate 20 Both ends are supported at both ends of the finger 10, respectively.

That is, since both ends of the interlock plate 20 are respectively supported at both ends of the finger 10, the finger 10 is moved in the axial direction and the interlock plate 20 is moved in the axial direction. However, the interlock plate 20 is configured to not rotate together when the finger 10 is rotated.

Meanwhile, referring to FIG. 6, the finger fork portion 11 of the present invention is formed by continuously connecting the finger protrusions 11a and the finger groove portions 11b along the axial direction of the outer circumferential surface of the finger 10.

In addition, the interlock fork portion 21 is formed by continuously connecting the interlock protrusion 21b and the interlock groove portion 21a between both ends of the interlock plate 20, the interlock fork portion 21 is the finger fork portion It is provided in a position facing (11).

In addition, the interlock fork portions 21 are provided on both sides of the finger fork portion 11, respectively.

In addition, as shown in Figures 3 and 4, the shift rail 40 is located in the lower portion of the control shaft 1, the axial direction of the shift rail 40 in a direction perpendicular to the axial direction of the finger 10 Is placed.

Then, one end of the jaw member 30 is inserted and coupled to the shift rail 40, and the shift rail 40 is moved in the axial direction according to the shifting movement of the jaw member 30.

In addition, as shown in FIGS. 5 and 6, a fork-shaped shift lug portion 31 is formed on the other end of the jaw member 30 opposite the selecting operation direction, and the shift lug portion 31 is a central shift lug. Shift lug protrusions 31b are formed on both sides of the groove portion 31a to form a structure.

At this time, since the shift lug groove portion 31a is formed in an open shape in the select operation direction, the finger fork portion 11 is structured to move in the select operation direction within the shift lug groove portion 31a. .

That is, the shift lug groove portion 31a is formed in a shape surrounding the lower end of the finger fork portion 11, whereby the finger protrusion 11a or the finger groove portion 11b is positioned in the shift lug groove portion 31a, The shift lug protrusion 31b is positioned between the finger fork portion 11 and the interlock protrusion 21b.

On the other hand, referring to Figure 6, the jaw member 30 of the present invention is configured to include a first jaw member 30a and a second jaw member 30b coupled to different shift rails 40.

For example, as shown in FIGS. 7 and 8, the first jaw member 30a may be operated to form a 1/R end in a low range, and to form a 4 end in a high range, and the second jaw member 30b Can be operated to form 2/3 stage in the low range and 5/6 stage in the high range. However, this is exemplified based on the shift pattern of FIG. 1, and the shift stage formed by the jaw member 30 may vary according to the structure of the shift pattern.

Particularly, in the present invention, when the other end of the first jaw member 30a is located between the finger protrusion 11a and the interlock groove 21a, the other end of the second jaw member 30b is the finger groove part 11b ) And the interlock protrusion 21b.

In addition, when the other end of the first jaw member 30a is located between the finger groove portion 11b and the interlock protrusion 21b, the other end of the second jaw member 30b is interlocked with the finger protrusion 11a. It is configured to be located between the grooves (21a).

That is, when the first jaw member 30a is in a position where the shifting operation of the 1/R stage is possible (between the finger protrusion 11a and the interlock groove portion 21a), the second jaw member 30b is adjacent It is configured to be positioned between the finger groove portion 11b and the interlock protrusion 21b, so that the shifting operation is impossible through the second jaw member 30b.

In addition, when the first jaw member 30a is in a position capable of shifting in four stages (between the finger protrusion 11a and the interlock groove 21a), the second jaw member 30b is a neighboring finger groove It is configured to be located between (11b) and the interlock protrusion 21b, so that the shifting operation is impossible through the second jaw member 30b.

Similarly, when the second jaw member 30b is in a position capable of shifting operation of 2/3 or 5/6 stages (between the finger protrusion 11a and the interlock groove portion 21a), the first jaw member (30a) is configured to be located between the neighboring finger groove portion (11b) and the interlock protrusion (21b) so that the shifting operation is impossible through the first jaw member (30a).

In addition, the present invention is formed so that the widthwise length of the finger protruding portion 11a formed in the center of the finger fork portion 11 forms a two-step selection operation interval, and the fingers leading to both sides of the central finger protruding portion 11a The lengths in the width direction of the grooves 11b and the finger protrusions 11a are formed to form a selection operation interval in one step.

And, the width of the interlock groove 21a formed in the center of the interlock fork portion 21 corresponding to the central finger protrusion 11a is formed to form a two-step selection operation interval, and the central interlock groove portion ( 21a) The widthwise lengths of the interlock protrusions 21b and the interlock grooves 21a leading to both sides are formed to form a selection operation interval in one step.

Further, the width direction lengths of the other ends of the first jaw member 30a and the second jaw member 30b are formed to form a selection operation interval in one step.

In particular, the length in the width direction between the other end of the first jaw member 30a and the other end of the second jaw member 30b has a structure that is arranged at three stages of the selection operation interval.

That is, while the shift lug portion 31 of the second jaw member 30b is in a neutral position between 2/3 stages, as shown in FIGS. 2 and 7 (b), the shift lever is selected to the left by one step. When operated, as shown in (a) of FIG. 7, the shift lug portion 31 of the first jaw member 30a is formed with 1/R stage while the finger 10 and the interlock plate 20 are moved one step to the right. It is placed in a neutral position where possible.

However, in this state, the second jaw member 30b is disposed with a first jaw member 30a and a three-step selection operation interval, so that the second jaw member 30b is an interlock protrusion located at the left end. It is placed in a position facing the (21b), thereby making the shifting operation by the second jaw member 30b impossible.

On the other hand, when the shift lug portion 31 of the second jaw member 30b is in a neutral position between 2/3 stages, when the shift lever is selected one step to the right, it is shown in FIG. 8(a) and Likewise, as the finger 10 and the interlock plate 20 are shifted one step to the left, it is switched from a low range to a high range, whereby the shift lug portion 31 of the first jaw member 30a is formed in four stages. It will be placed in a neutral position where possible.

However, in this state, the second jaw member 30b is placed at a position facing the interlock protrusion 21b located at the second from the left, so shifting operation by the second jaw member 30b is impossible. Is done.

In addition, when the shift lug portion 31 of the first jaw member 30a is in a neutral position capable of forming four stages, when the shift lever is selected one step to the right, as shown in FIG. 8(b), As the finger 10 and the interlock plate 20 move one step to the left, the shift lug portion 31 of the second jaw member 30b is placed in a neutral position capable of forming 5/6 steps.

However, in this state, the first jaw member 30a is placed at a position facing the interlock protrusion 21b located at the right end, and thus the shifting operation by the first jaw member 30a is impossible. .

In this way, it is possible to switch the range between the low range and the high range according to the selection operation of the shift lever, as well as the selection operation for forming the main stage in the low range and high range.

In addition, in the selecting position for forming the main end, one jaw member 30 is capable of shifting operation, and the other jaw member 30 is configured such that shifting operation is impossible.

Therefore, the present invention implements to form one shift stage on the same shift gate, while mechanically preventing the interlock phenomenon in which the two shift stage gears are fastened at the same time, it is expensive to implement the existing malfunction prevention system. The parts can be removed, thereby simplifying the structure of the transmission mechanism, thereby reducing the cost of the vehicle.

On the other hand, the present invention has been described in detail only with respect to the specific examples described above, but it is apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and it is natural that such modifications and modifications belong to the appended claims. .

1: Control shaft
2: Power shift mechanism
10: finger
11: Finger fork part
11a: Finger protrusion
11b: Finger groove
12: Select rug home
20: interlock plate
21: interlock fork
21a: Interlock groove
21b: Interlock protrusion
30: jaw member
30a: first jaw member
30b: second jaw member
31: shift lug part
31a: shift lug groove
31b: shift lug protrusion
40: shift rail

Claims (8)

A finger that is moved in the axial direction to be selected, rotated about an axis, and shifted, and formed with a fork-shaped finger fork portion facing the shifting direction;
The fingers are moved in the direction of the selecting operation, and on both sides of the finger fork portion, a fork-shaped interlock fork portion is formed opposite the shifting operation direction, and the interlock groove portion of the interlock fork portion faces the finger protrusion of the finger fork portion, An interlock plate arranged such that the interlock protrusion of the interlock fork portion faces the finger groove portion of the finger fork portion; And
It is provided with a plurality, one end is fixed to the shift rail, the other end is located on any part of the finger fork portion and the interlock fork portion, the position of the other end facing the finger fork portion and the interlock fork portion according to the selection movement of the finger Jaw member is changed to a different position; including,
According to the shifting operation of the finger, a vehicle shift mechanism for shifting the shift rail in the axial direction while the other end of any one jaw member facing the finger protrusion moves into the interlock groove portion facing the same. The method according to claim 1,
It is further provided with a control shaft provided with a shifting actuation force,
The finger is coupled to the control shaft;
A transmission mechanism for a vehicle, characterized in that a select lug groove is formed on a part of the outer surface of the finger to provide a selecting actuation force to the finger through the select lug groove. The method according to claim 1,
Fingers are inserted into the shape surrounding a part of the outer circumferential surface of the control shaft;
A vehicle transmission mechanism, characterized in that both ends of the interlock plate are inserted into a control shaft and supported at both ends of a finger. The method according to claim 3,
The finger fork portion is formed by continuously connecting the finger protrusion and the finger groove along the axial direction of the outer peripheral surface of the finger;
The interlock fork portion is formed by continuously connecting the interlock protrusion and the interlock groove between both ends of the interlock plate, and is provided at a position facing the finger fork portion;
The interlock fork portion is a transmission mechanism for a vehicle, characterized in that provided on each side of the finger fork portion. The method according to claim 1,
The axial direction of the shift rail is arranged in a direction orthogonal to the axial direction of the finger;
One end of the jaw member is inserted and coupled to the shift rail;
At the other end of the jaw member, a fork-shaped shift lug portion is formed to face the selecting operation direction, and a shift lug groove portion in the center of the shift lug portion is formed in an open shape in a select operation direction, so that the finger fork portion is the shift lug. A transmission device for a vehicle, characterized in that it is moved in the direction of selecting operation within the groove. The method according to claim 1,
The jaw member comprises a first jaw member and a second jaw member coupled to different shift rails,
When the other end of the first jaw member is located between the finger protrusion and the interlock groove, configure the other end of the second jaw member to be located between the finger groove and the interlock protrusion;
When the other end of the first jaw member is located between the finger groove portion and the interlock protrusion, the vehicle transmission mechanism is characterized in that the other end of the second jaw member is configured to be located between the finger protrusion and the interlock groove. The method according to claim 6,
A widthwise length of the finger protrusion formed in the center of the finger fork portion is formed to form a selection operation interval of two stages;
The length of the finger groove portion and the width of the finger protrusion portion extending to both sides of the central finger protrusion portion are formed to form a selection operation interval in one step;
A widthwise length of the interlock groove formed in the center of the interlock fork portion corresponding to the central finger protrusion is formed to form a two-step selection operation interval;
The interlock protrusions leading to both sides of the central interlock groove portion and the width of the interlock groove portion are formed to form a selection operation interval in one step;
The transmission mechanism for a vehicle, characterized in that the first jaw member and the second jaw member have a length in the width direction of the other end forming a selection operation interval of one step. The method according to claim 7,
The vehicle transmission mechanism, characterized in that the length in the width direction between the other end of the first jaw member and the other end of the second jaw member is arranged at three stages of the selection operation interval.

Images