CN221125387U - Simulated pedal training device - Google Patents

Abstract

The utility model belongs to the technical field of automobile driving auxiliary training devices, and particularly relates to a simulated pedal training device which comprises an indicator and a pedal assembly, wherein the indicator is connected with the pedal assembly; the pedal assembly comprises an upper pedal and a bottom plate, and one end of the upper pedal is hinged with the bottom plate; the upper pedal can be driven to rotate upwards to reset by releasing the elastic potential energy; the distance of the upper pedal movement can be determined by the indicator. Through setting up the footboard subassembly, can place outside the car and carry out simulation training, be provided with the indicator simultaneously, can judge the distance that goes up the footboard and remove through the indicator to the student of being convenient for observes and masters the control of stroke, utilizes the cooperation between the eye foot to form muscle memory promptly.

Description

Simulated pedal training device

Technical Field

The utility model belongs to the technical field of automobile driving auxiliary training devices, and particularly relates to a simulated pedal training device.

Background

When a novice learns the driving skill of a motor vehicle, the novice driver can manually or automatically shift the vehicle type. How to grasp the control capability of the vehicle to start and stop smoothly, and how to train the vehicle smoothly when the manual transmission is shifted? The vehicle pedal control device has the core that the vehicle pedal control device can only be used for feeling and fumbling by students in traditional training, so that the vehicle pedal is not fully understood in correct use, the stability of the control pedal is poor, the training efficiency is low, the training time is long, and the like. In actual operation, new and old people cannot control the speed of the vehicle, start and stall, running of the vehicle, unstable parking and the like, influence the mind of learning the vehicle and generate anxiety, tension and fear.

The main reason is that the stroke distance of each pedal cannot be mastered by a novice in the process of first contacting the vehicle, and the pedals are positioned under the feet, so that the novice is not easy to observe; so that a long fumbling is required to develop a certain muscle memory. Meanwhile, when a driving school is trained, the training time on the vehicle is limited, and related training cannot be performed after the driving school gets off, so that improvement is needed.

Disclosure of utility model

Aiming at the technical problems, the utility model provides a simulated pedal training device which can perform pedal stroke control training outside a vehicle.

In order to solve the technical problems, the utility model adopts the following technical scheme:

A simulated pedal training device comprises an indicator and a pedal assembly, wherein the indicator is connected with the pedal assembly; the pedal assembly comprises an upper pedal and a bottom plate, and one end of the upper pedal is hinged with the bottom plate; the upper pedal can be driven to rotate upwards to reset by releasing the elastic potential energy; the distance of the upper pedal movement can be determined by the indicator.

The indicator is a scale, and the lower end of the scale is fixedly connected with the bottom plate.

The scale is a reed which is contacted with the upper pedal and can replace the first return spring.

The indicator is a scale, the lower end of the scale is hinged with the bottom plate, the scale is contacted with the upper pedal, and the upper pedal can drive the scale to rotate when rotating downwards; a second reset spring is arranged between the scale and the bottom plate, and the scale can be driven to reversely rotate and reset through the second reset spring.

The indicator is a scale, the lower end of the scale is hinged with the bottom plate, the scale is contacted with the upper pedal, and the upper pedal can drive the scale to rotate when rotating downwards; a second reset spring is arranged between the scale and the bottom plate, and the scale and the upper pedal can be driven to reversely rotate and reset through the second reset spring; the first return spring can be replaced by a second return spring.

The lower extreme of scale is articulated with the bottom plate, scale and last footboard sliding connection.

The first reset spring adopts a pressure spring, a torsion spring or a spring piece; when the pressure spring is adopted, two ends of the pressure spring are respectively and fixedly connected with the upper pedal and the bottom plate; when the torsion spring is adopted, the torsion spring is arranged at the hinge joint between the upper pedal and the bottom plate or between the upper pedal and the bottom plate; when the spring piece is adopted, the spring piece is arranged at the hinge joint between the upper pedal and the bottom plate or between the upper pedal and the bottom plate.

The indicating piece comprises a movable scale and a connecting rod, and the movable scale is in sliding connection with the upper pedal; the two ends of the connecting rod are respectively hinged or fixedly connected with the movable scale and the bottom plate, and the connecting rod is an elastic piece during the fixed connection.

A third reset spring is arranged between the movable scale or the connecting rod and the bottom plate or the upper pedal, and the movable scale can be driven to reset through the third reset spring.

A third reset spring is arranged between the movable scale or the connecting rod and the bottom plate or the upper pedal, and the movable scale can be driven to reset and the upper pedal can be driven to rotate and reset through the third reset spring; the first return spring can be replaced by a third return spring.

Compared with the prior art, the utility model has the beneficial effects that:

Through setting up the footboard subassembly, can place outside the car and carry out simulation training, be provided with the indicator simultaneously, can judge the distance that goes up the footboard and remove through the indicator to the student of being convenient for observes and masters the control of stroke, utilizes the cooperation between the eye foot to form muscle memory promptly.

Drawings

FIG. 1 is a schematic view showing the structure of one direction of embodiment 2.1 of the present utility model;

FIG. 2 is a schematic view showing the structure of the embodiment 2.1 of the present utility model in another direction;

FIG. 3 is a schematic view showing the structure of embodiment 2.2 of the present utility model in one direction;

FIG. 4 is a schematic view showing the structure of the embodiment 2.2 of the present utility model in another direction;

FIG. 5 is a schematic structural view of embodiment 2.3 of the present utility model;

FIG. 6 is a schematic structural view of embodiment 2.4 of the present utility model;

FIG. 7 is a schematic view showing another construction of embodiment 2.4 of the present utility model;

FIG. 8 is a schematic view of the structure of embodiment 2.5 of the present utility model;

FIG. 9 is a schematic view showing another construction of embodiment 2.5 of the present utility model;

FIG. 10 is a schematic view showing a structure of embodiment 3 of the present utility model;

FIG. 11 is a schematic view showing another structure of embodiment 3 of the present utility model;

fig. 12 is a schematic structural view of embodiment 3.1 of the present utility model;

fig. 13 is a schematic structural view of embodiment 3.2 of the present utility model;

FIG. 14 is a schematic view of the hinge position of the upper pedal and the bottom plate of the present utility model;

Wherein: 1 is an indicator, 2 is a pedal assembly, 20 is an upper pedal, 21 is a bottom plate, 22 is a first return spring, 3 is a second return spring, 4 is a connecting ring, 5 is a movable scale, 6 is a connecting rod, 7 is a third return spring, 8 is a chute, 9 is a through hole, and 10 is a bolt.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

A simulated pedal training device comprises an indicator 1 and a pedal assembly 2, wherein the indicator 1 is connected with the pedal assembly 2; the pedal assembly 2 comprises an upper pedal 20 and a bottom plate 21, wherein one end of the upper pedal 20 is hinged with the bottom plate 21; the upper pedal 20 can be rotated downwards by the first return spring 22, so that the first return spring 22 can generate elastic potential energy, and the first return spring 22 releases the elastic potential energy to drive the upper pedal 20 to rotate upwards for return; the control pedal on the automobile can be simulated. And the distance that the upper pedal 20 moves can be judged by the indicator 1.

When in use, the pedal assembly 2 is placed or fixed on the ground; then, the upper pedal 20 is stepped on, and the moving distance of the upper pedal 20 is determined by the position change between the upper pedal 20 and the indicator 1. Taking the simulated clutch pedal as an example, a reference point (semi-linkage) can be found on the indicator 1, and when the pedal 20 is stepped on by foot, the other end of the upper pedal 20 is gradually flush with the reference point on the indicator 1, so that the stroke control of the semi-linkage position is realized.

The indicator 1 of the above embodiment 1 may be provided on the base plate 21, and specifically may employ a scale having graduations thereon so as to find the corresponding graduations on the scale according to the pedal travel position on the vehicle. Taking a clutch pedal as an example, the angle measurement is firstly carried out on a vehicle: the left foot is grounded, then the clutch is stepped down and gradually lifted up, and when the left foot reaches the half-linkage position, the inclination angle of the left foot is recorded.

Then the upper pedal 20 of the device is stepped on by foot, so that the inclination angle of the left foot is consistent with the angle measured by the above semi-linkage position, and the corresponding scale points are found on the scale. At this time, during training, only the pedal 20 is needed to be stepped on by foot to control the lifting to the half-linkage position (the foot control is observed through eyes); the control of the half-linkage stroke can be mastered by the cyclic exercise, the stroke muscle memory is gradually achieved, and the training on a vehicle is not needed.

As shown in fig. 1 and 2, the indicator 1 is a scale, which specifically adopts a fixed connection mode: namely, the lower end of the scale is fixedly connected with the bottom plate 21; by adopting the method, the scale points are found on the scale, and then training can be performed.

In the above embodiment 2.1, the upper pedal 20 is reset by the first reset spring 22 by stepping on the upper pedal 20; however, when the scale is a straight scale, there is a gap between the scale and the upper pedal 20, so that the scale is easily inclined in a dislocation manner when the scale is observed; therefore, the following technical scheme is adopted to overcome:

As shown in fig. 3 and 4, the scale is a reed, which is in contact with the upper pedal 20, i.e., the scale can always be in contact with the upper pedal 20, thereby avoiding a gap therebetween and preventing dislocation during observation of the scale. Preferably, it may be a curved reed.

When the reed is adopted, the upper pedal 20 can be bent to generate elastic potential energy after moving downwards, and when the elastic potential energy is released, the upper pedal 20 can be pushed to reset, so that the first reset spring 22 can be omitted, namely, the first reset spring 22 can be replaced by the structure.

The above embodiments 2.1 and 2.2 use a fixed connection to connect the scale to the base plate 21, although it may also use a hinged connection, as described in detail below:

as shown in fig. 5, the indicator 1 is a scale, the lower end of the scale is hinged with the bottom plate 21, and the scale is contacted with the upper pedal 20; a second reset spring 3 is arranged between the scale and the bottom plate 21, and can drive the scale to rotate when the upper pedal 20 rotates downwards, namely the scale can be always attached to the upper pedal 20; and the second return spring 3 generates elastic potential energy, and when the upper pedal 20 rotates upwards, the scale is driven to reversely rotate and return by releasing the elastic potential energy through the second return spring 3.

In the above embodiment 2.3, two return springs are provided, one for returning the upper pedal 20 and the other for returning the scale. Meanwhile, due to the arrangement of the structure, the second return spring 3 can replace the first return spring 22, namely, only the second return spring 3 is arranged, and the following details are shown in the specification:

as shown in fig. 6 and 7, the indicator 1 is a scale, the lower end of the scale is hinged with the bottom plate 21, the scale is contacted with the upper pedal 20, and the upper pedal 20 can drive the scale to rotate when rotating downwards; a second reset spring 3 is arranged between the scale and the bottom plate 21, and can drive the scale to rotate when the upper pedal 20 rotates downwards, namely the scale can be always attached to the upper pedal 20; and the second return spring 3 generates elastic potential energy, when the foot is lifted, the second return spring 3 releases the elastic potential energy to drive the scale to reversely rotate and return, and the upper pedal 20 can be pushed to return in the process of reversely rotating the scale. I.e. the first return spring 22 can be replaced by the second return spring 3.

In the above arrangements 2.3 and 2.4, the second return spring 3 is required to be arranged to realize the return of the scale; of course, the following structure may be adopted to realize the resetting of the scale.

Specific: as shown in fig. 8, the lower end of the scale is hinged with the bottom plate 21, and the scale is slidably connected with the upper pedal 20; the sliding connection can be realized by adopting various structures, for example, a connecting ring 4 is fixed on the upper pedal 20, the upper end of the staff gauge can extend out through the connecting ring 4, and the staff gauge can slide along the connecting ring 4; namely, the upper pedal 20 can be moved to drive the scale to rotate and the scale to reversely rotate for resetting through the cooperation between the connecting ring 4 and the scale.

Similarly, the semi-rings can be arranged, or the semi-rings can be adsorbed by the magnets, or similar structures such as sliding grooves can be arranged, and the semi-rings can be connected in a sliding way no matter what way is adopted.

Similarly, as shown in fig. 9, the length of the bottom plate 21 may be lengthened so that the scale is inclined to fit (slide fit) with the upper pedal 20; this also allows the upper pedal 20 to move and cooperate with the scale to rotate and return the scale in reverse rotation.

Further, the same applies to the second return spring 3 as long as the scale rotation return can be achieved; such as: it can use compression spring, tension spring, torsion spring, or even rubber band.

Taking a pressure spring as an example, two ends of the pressure spring are respectively fixedly connected or hinged with the scale and the bottom plate 21; as shown in fig. 6, for example, a tension spring is used, and two ends of the tension spring are fixedly connected or hinged with the scale and the bottom plate 21 (or the upper pedal 20) respectively; taking a torsion spring as an example, it is provided at the hinge between the scale and the base plate 21; the hinge part is to sleeve the torsion spring on the hinge shaft, or to connect the two ends of the torsion spring with the scale and the bottom plate 21 (or the upper pedal 20) respectively (fixedly connected or hinged). As shown in fig. 7, for example, the two ends of the elastic band are fixedly connected or hinged with the scale and the bottom plate 21 (or the upper pedal 20), respectively.

In the above embodiment 2 (including 2.1 to 2.5), the arrangement that the scale is connected to the bottom plate 21 is adopted, and in this embodiment, the scale is connected to the upper pedal 20.

As shown in fig. 10 and 11, the indicator 1 includes a movable scale 5 and a connecting rod 6, the movable scale 5 being slidably connected with the upper pedal 20; two ends of the connecting rod 6 are respectively hinged with the movable scale 5 and the bottom plate 21; similarly, a corresponding reference point (scale) is found on the movable scale 5, and the reference point position is found as in example 2. When the upper pedal 20 rotates, the staff gauge can be driven to move through the connecting rod 6, and when the top of the other end of the upper pedal 20 moves to the reference point position, the staff gauge is in a semi-linkage position.

Meanwhile, the connecting rod 6 is hinged; it can of course be connected in a fixed manner to the movable scale 5 and to the base plate 21; however, when a fixed connection is adopted, the connecting rod 6 needs to be an elastic piece, and the elastic piece deforms when the upper pedal 20 moves so as to drive the movable scale 5 to slide.

For sliding connection, a corresponding chute 8 (as shown in fig. 10) may be provided on the upper pedal 20, and the movable scale 5 may be provided in the chute 8; of course, a through hole 9 (as shown in fig. 11) can be arranged in the middle of the movable scale 5, a bolt 10 connected with the upper pedal 20 is arranged at the through hole 9, and sliding connection can be realized; that is, no matter what structure is adopted, the sliding connection between the two is realized.

In the above embodiment 3, only one return spring is provided, that is, the return of the upper pedal 20 is achieved by the first return spring 22, and the scale is driven to slide and return by the connecting rod 6.

Of course, two return springs may be provided, as described in detail below:

As shown in fig. 12, a third return spring 7 is provided between the movable scale 5 or the connecting rod 6 and the bottom plate 21, and the movable scale 5 can be driven to return by the third return spring 7. Namely, when the upper pedal 20 rotates, the connecting rod 6 is driven to rotate so that the third reset spring 7 generates elastic potential energy, and when the third reset spring releases the elastic potential energy, the movable scale 5 is driven to reset through the connecting rod 6.

Namely, by arranging two return springs, the third return spring 7 realizes the return of the movable scale 5, and the first return spring 22 realizes the return of the upper pedal 20.

In the above embodiment 3, only one return spring, namely, the first return spring 22 is provided, the return of the upper pedal 20 is realized by the first return spring 22, and the movable scale 5 is driven to slide and return by the connecting rod 6; of course, the third return spring 7 may be provided between the movable scale 5 or the connecting rod 6 and the bottom plate 21, and the first return spring 22 may be replaced by the third return spring 7, as described below:

As shown in fig. 13, a third reset spring 7 is arranged between the movable scale 5 or the connecting rod 6 and the bottom plate 21, and the connecting rod 6 and the movable scale 5 can be driven to reset and the upper pedal 20 can be driven to rotate and reset by releasing elastic potential energy through the third reset spring 7; the third return spring 7 can replace the first return spring 22.

Further, with the third return spring 7 in the above-described embodiments 3 to 3.2, it is only necessary to achieve rotational return of the connecting rod 6; such as: it can use compression spring, tension spring, torsion spring, or even rubber band.

Taking a pressure spring as an example, two ends of the pressure spring are respectively fixedly connected or hinged with the connecting rod 6 and the bottom plate 21; taking a tension spring as an example, two ends of the tension spring are respectively fixedly connected or hinged with the connecting rod 6 (or the movable scale 5) and the bottom plate 21 (or the upper pedal 20); taking torsion springs as an example, which are provided at the hinge between the connecting rod 6 and the bottom plate 21; taking rubber bands as an example, two ends are respectively fixedly connected or hinged with the connecting rod 6 (or the movable scale 5) and the bottom plate 21 (or the upper pedal 20). The specific connection setting of the third return spring 7 can be adjusted according to actual needs.

Further, the first return spring 22 in the above embodiments 1 to 3 employs a compression spring, a torsion spring or a leaf spring; regardless of the structure, the resetting of the upper pedal 20 can be realized; the method comprises the following steps: when the pressure spring is adopted, two ends of the pressure spring are fixedly connected with the upper pedal 20 and the bottom plate 21 respectively; when the torsion spring is adopted, the torsion spring is arranged at the hinge joint between the upper pedal 20 and the bottom plate 21, wherein the hinge joint means that the torsion spring is sleeved on a hinge shaft, or two ends of the torsion spring are respectively connected with the upper pedal 20 and the bottom plate 21 (can be fixedly connected or hinged); when the spring plate is adopted, two ends of the spring plate are respectively connected with the upper pedal 20 and the bottom plate 21 (which can be fixedly connected or hinged).

Similarly, the hinge position between the upper pedal 20 and the bottom plate 21 in the above embodiments 1-3 can be adjusted according to practical situations, and specifically, the following hinge positions can be adopted:

One end of the upper pedal 20 may be hinged with the top, side or bottom surface of the bottom plate 21; meanwhile, it may be hinged with the top, side or bottom end or middle of the bottom plate 21 in particular. The above specific connection positions are shown in fig. 14, in which a-c are schematic views of the hinge positions of one end of the upper pedal 20 and the end of the top, side or bottom of the bottom plate 21, respectively; where d-f are schematic illustrations of the hinge positions of one end of the upper deck 20 and the middle of the top, side or bottom of the bottom deck 21, respectively.

The preferred embodiments of the present utility model have been described in detail, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model, and the various changes are included in the scope of the present utility model.

Claims (10)

1. A simulated pedal training device, characterized by: the pedal comprises an indicator (1) and a pedal assembly (2), wherein the indicator (1) is connected with the pedal assembly (2); the pedal assembly (2) comprises an upper pedal (20) and a bottom plate (21), and one end of the upper pedal (20) is hinged with the bottom plate (21); the pedal comprises an upper pedal (20) and is characterized by further comprising a first return spring (22), wherein the first return spring (22) can generate elastic potential energy when the upper pedal (20) rotates downwards, and the first return spring (22) releases the elastic potential energy and can drive the upper pedal (20) to rotate upwards for return; the distance of movement of the upper pedal (20) can be determined by the indicator (1).

2. A simulated pedal training device as claimed in claim 1 wherein: the indicator (1) is a scale, and the lower end of the scale is fixedly connected with the bottom plate (21).

3. A simulated pedal training device as claimed in claim 2 wherein: the scale is a reed which is in contact with the upper pedal (20) and can replace the first return spring (22).

4. A simulated pedal training device as claimed in claim 1 wherein: the indicator (1) is a scale, the lower end of the scale is hinged with the bottom plate (21), the scale is contacted with the upper pedal (20), and the upper pedal (20) can drive the scale to rotate when rotating downwards; a second reset spring (3) is arranged between the scale and the bottom plate (21), and the scale can be driven to reversely rotate and reset through the second reset spring (3).

5. A simulated pedal training device as claimed in claim 1 wherein: the indicator (1) is a scale, the lower end of the scale is hinged with the bottom plate (21), the scale is contacted with the upper pedal (20), and the upper pedal (20) can drive the scale to rotate when rotating downwards; a second reset spring (3) is arranged between the scale and the bottom plate (21), and the scale and the upper pedal (20) can be driven to reversely rotate and reset through the second reset spring (3); the first return spring (22) can be replaced by a second return spring (3).

6. A simulated pedal training device as claimed in claim 1 wherein: the indicator (1) is a scale, the lower end of the scale is hinged with the bottom plate (21), and the scale is in sliding connection with the upper pedal (20).

7. A simulated pedal training device as claimed in claim 1 wherein: the first return spring (22) adopts a pressure spring, a torsion spring or a spring piece; when the pressure spring is adopted, two ends of the pressure spring are fixedly connected with the upper pedal (20) and the bottom plate (21) respectively; when the torsion spring is adopted, the torsion spring is arranged between the upper pedal (20) and the bottom plate (21) or between the upper pedal (20) and the bottom plate (21); when the spring piece is adopted, the spring piece is arranged at the hinge joint between the upper pedal (20) and the bottom plate (21) or between the upper pedal (20) and the bottom plate (21).

8. A simulated pedal training device as claimed in claim 1 wherein: the indicator (1) comprises a movable scale (5) and a connecting rod (6), and the movable scale (5) is in sliding connection with the upper pedal (20); the two ends of the connecting rod (6) are respectively hinged or fixedly connected with the movable scale (5) and the bottom plate (21), and the connecting rod (6) is an elastic piece during the fixed connection.

9. A simulated pedal training device as claimed in claim 8 wherein: a third reset spring (7) is arranged between the movable scale (5) or the connecting rod (6) and the bottom plate (21) or the upper pedal (20), and the movable scale (5) can be driven to reset through the third reset spring (7).

10. A simulated pedal training device as claimed in claim 8 wherein: a third reset spring (7) is arranged between the movable scale (5) or the connecting rod (6) and the bottom plate (21) or the upper pedal (20), and the movable scale (5) can be driven to reset and the upper pedal (20) can be driven to rotate and reset through the third reset spring (7); the first return spring (22) can be replaced by a third return spring (7).