CN222061889U - Auxiliary instrument board assembly and automobile - Google Patents

Abstract

The application provides a secondary instrument board assembly and an automobile, the auxiliary instrument board assembly comprises an assembly shell and a cup stand mechanism, wherein the assembly shell encloses a storage bin with an opening. The cup holder mechanism comprises a shell and a cup holder assembly which is connected with the shell in a sliding way; the cup stand component can be exposed in the storage bin and hidden in the assembly shell through sliding. When the cup stand is realized, the sliding and locking of the cup stand component can be realized through the cooperation of the driving mechanism and the locking structure. The driving mechanism is used for driving the cup holder assembly to slide from the second set position to the first set position and limiting the cup holder assembly at the first set position; and a locking mechanism for locking the cup holder assembly in the second set position. Through the mode that adopts the saucer subassembly to slide the setting, when not using the saucer subassembly, can hide it in the casing to can change the loading space of storing storehouse, in addition, through the cooperation of actuating mechanism and locking mechanical system, can realize popping out in the automation of saucer subassembly, the position of convenient adjustment saucer subassembly.

Description

Auxiliary instrument board assembly and automobile

Technical Field

The application relates to the technical field of automobiles, in particular to a secondary instrument board assembly and an automobile.

Background

The auxiliary instrument board assembly is used for bearing sundries of a user. But the storage space of the current sub fascia assembly is fixed. Some have a separate space for receiving the cup. But this results in less space for carrying other items. There is no space to accommodate the cup alone, which may result in an inability to secure the cup well. Thus, the auxiliary instrument board assembly cannot be suitable for different scenes.

Disclosure of utility model

The application provides a secondary instrument board assembly and an automobile, and improves the use effect of the secondary instrument board assembly.

The application provides a sub-instrument panel assembly, comprising: an assembly housing and a cup holder mechanism; wherein,

The assembly shell encloses a storage bin with an opening;

the cup holder mechanism comprises a shell fixed in the assembly shell and a cup holder assembly slidingly assembled in the shell; wherein, when the cup holder assembly slides to a first set position, the cup holder assembly is exposed in the storage bin; when the cup holder assembly slides to a second set position, the cup holder assembly is hidden into the assembly housing;

The cup stand mechanism further comprises a driving mechanism and a locking mechanism; wherein, the driving mechanism and the locking mechanism are positioned at one side of the cup holder assembly, which is away from the opening of the storage bin;

the driving mechanism is used for driving the cup holder assembly to slide from the second setting position to the first setting position;

The locking mechanism comprises an elastic sheet arranged on the cup holder assembly and a labyrinth guide rail arranged on the bottom plate of the shell; when the cup holder assembly slides to the second setting position, the elastic piece is locked with the labyrinth guide rail, and the cup holder assembly is locked at the second setting position.

In the technical scheme, the cup stand assembly is arranged in a sliding manner, so that the cup stand assembly can be hidden in the shell when not in use, the bearing space of the storage bin can be changed, different scenes can be adapted, and the adaptability of the auxiliary instrument assembly is improved. In addition, through the cooperation of actuating mechanism and locking mechanical system, can realize popping out in the automation of saucer subassembly, the position of convenient adjustment saucer subassembly.

In a specific embodiment, the driving mechanism is an elastic member, and the elastic member drives the cup holder assembly to slide from the second setting position to the first setting position through elastic force.

In a specific embodiment, the drive mechanism is a coil spring; one end of the coil spring is fixedly connected with the bottom plate of the shell, and the other end of the coil spring is fixedly connected with the cup holder assembly.

In a specific embodiment, the cup holder assembly comprises a cup holder body and a base fixedly connected to the cup holder body; wherein,

The cup stand body is connected with the shell in a sliding way; one end of the coil spring is fixedly connected with the base, and the elastic sheet is fixedly connected with the base.

In a specific embodiment, the cup holder body is fixedly connected to the base by a threaded connection.

In a specific embodiment, the number of the driving mechanisms is two, and the two driving mechanisms are respectively arranged at two opposite sides of the locking mechanism along the first direction; wherein,

The first direction is perpendicular to a sliding direction of the cup holder assembly.

In a specific possible embodiment, the cup holder mechanism further comprises a damping assembly comprising a damping rack disposed on the bottom plate of the housing, and a damping gear engaged with the damping rack;

The damping gear is rotationally connected with the cup stand assembly;

the length direction of the damping rack is along the sliding direction of the cup holder assembly.

In a specific implementation manner, the labyrinth guide rail comprises a groove body formed in the bottom plate of the shell, and a guide block and a locking block which are arranged in the groove body; wherein,

The length direction of the groove body is along the sliding direction of the cup holder assembly, and the guide blocks and the locking blocks are arranged at intervals along the sliding direction of the cup holder assembly; the locking block is positioned at one end far away from the storage bin; one end of the locking block, which is away from the storage bin, is provided with a locking notch;

The guide block and the locking block divide the groove body into a first guide rail and a second guide rail which are crossed in an X shape;

When the cup holder assembly slides from a first setting position to a second setting position, the elastic piece slides to the locking notch along the first guide rail and is locked;

When the cup holder assembly slides from the second setting position to the first setting position, the elastic piece slides out of the locking notch and slides along the second guide rail to one end of the second guide rail, which is close to the storage bin.

In a specific embodiment, the housing is provided with guide rails on opposite side walls, and the cup holder assembly is provided with a slider slidably engaged with each guide rail.

In a second aspect, an automobile is provided that includes a body and any one of the above sub-fascia assemblies secured to the body.

In the technical scheme, the cup stand assembly is arranged in a sliding manner, so that the cup stand assembly can be hidden in the shell when not in use, the bearing space of the storage bin can be changed, different scenes can be adapted, and the adaptability of the auxiliary instrument assembly is improved. In addition, through the cooperation of actuating mechanism and locking mechanical system, can realize popping out in the automation of saucer subassembly, the position of convenient adjustment saucer subassembly.

Drawings

FIG. 1 is a schematic view of a cup holder mechanism in a dashboard assembly according to an embodiment of the present application;

FIG. 2 is an exploded view of a cup holder mechanism provided in an embodiment of the present application;

Fig. 3 is a schematic view of a bottom plate of a housing according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be further described in detail with reference to the accompanying drawings.

It is noted that unless otherwise defined, technical or scientific terms used in one or more embodiments of the present disclosure should be taken in a general sense as understood by one of ordinary skill in the art to which the present disclosure pertains. The use of the terms "first," "second," and the like in one or more embodiments of the present description does not denote any order, quantity, or importance, but rather the terms "first," "second," and the like are used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that elements or items preceding the word are included in the element or item listed after the word and equivalents thereof, but does not exclude other elements or items. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", etc. are used merely to indicate relative positional relationships, which may also be changed when the absolute position of the object to be described is changed.

In order to facilitate understanding of the auxiliary instrument board assembly provided by the embodiment of the application, an application scene of the auxiliary instrument board assembly is first described. The auxiliary instrument board assembly provided by the embodiment of the application is applied to a vehicle and is used for bearing articles of users. The total composition of the current auxiliary instrument board is two kinds, or is the structure without the saucer, and the storing space of auxiliary instrument board assembly is an holistic storing space at this moment, and when needs place the cup, be difficult for fixing. The other is a structure with a cup stand of the auxiliary instrument board assembly, and the storage space is divided into two spaces by the cup stand structure, so that the space for bearing other articles is smaller. Therefore, the embodiment of the application provides a secondary instrument board assembly, which is used for improving the bearing effect of the secondary instrument board assembly. The following detailed description is made with reference to the specific drawings and examples.

The auxiliary instrument board assembly main body structure provided by the embodiment of the application comprises an assembly shell and a cup stand mechanism. Wherein, the assembly shell forms the exterior structure of vice instrument board assembly, and it encloses into the storing storehouse that has the opening. And the cup stand mechanism is used for bearing the water cup. During specific assembly, the cup stand mechanism is fixed in the assembly shell and is used for being matched with the storage bin. When the cup stand mechanism is particularly matched, the cup stand mechanism is provided with a drawable cup stand component which is used for bearing a cup. When the cup stand component is pulled out, the cup stand component can be positioned in the storage bin, so that the function of bearing a cup is realized; meanwhile, the space of the storage bin can be divided into a space for bearing the water cup and a space for bearing other objects by the cup holder assembly; when the cup holder assembly is restored to the initial state, the cup holder assembly is hidden in the assembly shell, and the whole storage bin can be used for bearing other objects. Therefore, the instrument board assembly provided by the embodiment of the application changes the bearing effect of the storage bin mainly through the cooperation of the cup stand mechanism and the assembly shell. The cup holder mechanism and its cooperation with the assembly housing are described in detail below in conjunction with the specific figures.

Referring to fig. 1 and 2, fig. 1 shows a schematic structural diagram of a cup holder mechanism according to an embodiment of the present application; fig. 2 shows an exploded view of the cup holder mechanism.

The cup holder mechanism main body structure provided by the embodiment of the application comprises a shell 20 and a cup holder assembly 10 positioned in the shell 20. When specifically disposed within the assembly housing 20, the housing 20 is secured within the assembly housing 20 to secure the entire cup holder mechanism. When the fixing is specifically performed, the fixing connection can be performed by means of clamping, bonding or threaded connection (bolts or screws) and the like. It should be understood that when the housing 20 is secured within the assembly housing, the housing 20 is positioned to clear the storage compartment, and it is also understood that the housing 20 is hidden within the assembly housing. Of course, the housing 20 may also be of unitary construction with the assembly housing.

The housing 20 serves as a support structure for supporting the cup holder assembly 10. When the cup holder assembly 10 is mated with the housing 20, the cup holder assembly 10 is positioned within the housing 20 and slidably coupled to the housing 20. So that the cup holder assembly 10 can slide in and out of the housing 20. The housing 20 and the cup holder assembly 10 are hidden within the assembly housing and adjacent the storage bin when the housing 20 and the cup holder assembly 10 are assembled within the assembly housing, and the cup holder assembly 10 can slide back and forth when it slides relative to the housing 20. For ease of description, two end positions of the slide of the cup holder assembly 10 are defined, a first set position and a second set position, respectively. When the cup holder assembly 10 is slid to the first set position, the cup holder assembly 10 is exposed within the storage bin. At this time, the cup holder assembly 10 occupies a part of the space of the storage bin, and the space in the storage bin is divided into a space for bearing the cups (the cup holder assembly 10) and a space for bearing other objects through the cup holder assembly 10. When the cup holder assembly 10 is slid to the second set position, the cup holder assembly 10 is positioned to be hidden within the housing 20 (i.e., within the assembly housing), such that the entire storage bin can be used to carry other items. Therefore, the storage bin can be divided into different spaces to bear articles according to the requirements. When it is desired to carry a cup, the cup holder assembly 10 can be slid out and exposed to the storage bin for carrying. When the cup is not needed to be carried, the cup holder assembly 10 can be slid into the assembly housing, and the storage bin has a larger space for carrying other objects.

As shown in fig. 2, the housing 20 has an open structure at two ends, and includes four side walls, specifically including a top plate 21, a left side plate 23, a right side plate 24, and a bottom plate 22, where the top plate 21, the left side plate 23, the right side plate 24, and the bottom plate 22 are sequentially connected to form a frame-type housing 20. When the cup holder assembly 10 is slidably coupled to the housing 20, the sliding direction thereof is along the alignment direction of the two ports of the housing 20. When the shell 20 is fixed in the assembly housing, an open end of the shell 20 faces the storage bin and the shell 20 is adjacent to the storage bin, so that when the cup holder assembly 10 in the shell 20 slides out, the cup holder assembly 10 can be positioned in the storage bin and used for bearing a cup. When the cup holder assembly 10 is slid into the housing 20, the cup holder assembly 10 can be hidden within the assembly housing and does not occupy the storage compartment space.

The housing 20 illustrated above is a specific structure, and the housing 20 provided in the embodiment of the present application may be arranged in other manners. The housing 20 according to the embodiment of the present application may also be a housing 20 with an opening at one end. Other arrangements are of course possible depending on the function of the housing 20 primarily to support the sliding movement of the cup holder assembly 10. For convenience of description, the cup holder mechanism provided in the embodiment of the present application will be described by taking the structure of the housing 20 shown in fig. 2 as an example.

The cup holder assembly 10 can slide through the cooperation of the slider and the guide rail when slidably connected to the housing 20. As shown in fig. 2, the housing 20 is provided with guide rails on opposite side walls thereof, and the cup holder assembly 10 is provided with a slider slidably fitted with each guide rail. When the housing 20 includes the left side plate 23 and the right side plate 24, two guide rails are respectively disposed on the left side wall and the right side wall, so as to provide stability of the cup holder assembly 10 during sliding by respectively sliding the opposite two side walls of the cup holder assembly 10 with the corresponding side walls.

In addition, it should be understood that the manner of slidably connecting the cup holder assembly 10 and the housing 20 is not limited to the manner of sliding blocks and guide rails described in the above examples, and other manners of sliding may be adopted, which are not illustrated in the embodiments of the present application.

With continued reference to fig. 2, as one specific example of the cup holder assembly 10, the cup holder assembly 10 includes a cup holder body 11 and a base 12. Wherein the cup holder body 11 is used for bearing a cup, and is provided with a cavity for bearing the cup. In one example cup holder body 11, it can be made by two-shot molding such that there are both softer cup-gripping protrusions in the side walls of the cavity and harder cup-supporting side walls.

When the cup holder assembly 10 is in sliding connection with the shell 20, the cup holder assembly 11 and the shell 20 can be connected in a sliding connection mode. For example, the slider may be disposed on the cup holder body 11 when the slider and guide rail are used to achieve the sliding connection of the cup holder assembly 10 to the housing 20. So that the cup holder assembly 10 can support the cup holder body 11 through the cooperation of the slider and the guide rail when sliding.

The base 12 is fixedly connected to the cup holder body 11, and the base 12 serves as a component of the cup holder assembly 10 for cooperation with the drive mechanism 50 and the locking mechanism 30. When the base 12 is specifically provided, the base 12 is located at a side facing away from the opening of the cavity of the cup holder body 11 and is fixedly connected with the cup holder body 11, such as by a threaded connection, welding, or other different manners. As a specific example, the base 12 is coupled to the cup holder assembly 10 using a threaded connection to facilitate easy removal and replacement in the event of damage to either of the cup holder assembly 10 or the base 12.

Referring to fig. 2 and 3 together, fig. 3 illustrates a schematic structure of the bottom plate 22 of the housing 20. The drive mechanism 50 is required to drive the cup holder assembly 10 when it slides in and out of the housing 20, and the locking catch is required to lock. The two mechanisms are described below.

First, a description is given of the driving mechanism 50. The driving mechanism 50 according to the embodiment of the present application is a unidirectional driving mechanism 50, and the driving mechanism 50 can be used to drive the cup holder assembly 10 to slide from the second setting position to the first setting position.

When specifically provided, the drive mechanism 50 is disposed on a side of the cup holder assembly 10 facing away from the opening of the storage bin, such that the drive mechanism 50 is shielded by the cup holder assembly 10. The side of the cup holder assembly 10 that is opposite to the opening of the storage bin is specifically referred to as the side of the cup holder assembly 10 that faces away from the opening of the storage bin along the height direction. When the above-mentioned mode is adopted, the driving mechanism 50 is arranged below the cup holder assembly 10 (taking the placement direction of the cup holder assembly 10 in fig. 1 as the reference direction), so that the driving mechanism 50 can utilize the gap between the cup holder assembly 10 and the bottom plate 22 of the shell 20 to set, and meanwhile, the top surface of the cup holder assembly 10 can reduce the overlarge gap between the top plate 21 of the shell 20 and the cup holder assembly 10 when the top surface slides out, so that the appearance of the auxiliary instrument board assembly is affected.

As an example, the driving mechanism 50 provided by the embodiment of the present application may be an elastic member, and the elastic member may drive the cup holder assembly 10 to slide from the second setting position to the first setting position by using elastic force. The resilient member is elastically deformed and stretched as the cup holder assembly 10 slides from the first set position to the second set position. When the cup holder assembly 10 slides from the second setting position to the first setting position, the elastic member returns to the original state.

Illustratively, the resilient member can be a coil spring having one end fixedly coupled to the base 22 of the housing 20 and the other end fixedly coupled to the cup holder assembly 10. When specifically arranged, one end of the coil spring is fixed at one end of the bottom plate 22 close to the storage bin; the other end is fixed at the end of the cup holder assembly 10 hidden in the housing 20, such as at the end of the base 12 remote from the storage bin. When the cup holder assembly 10 slides from the first set position to the second set position, the coil spring is stretched and expanded; when the cup holder assembly 10 is slid from the second set position to the first set position, the coil spring returns to the original state. With the above structure, the coil spring can provide a stable elastic force, so that the cup holder assembly 10 can slide out in a stable state when sliding out.

The elasticity will be that a tension spring may be used in addition to the coil springs of the above examples, and one end of the tension spring is fixed to the cup holder assembly 10, specifically, the base 12 of the cup holder assembly 10. The other end of the tension spring is disposed on the housing 20, specifically on the bottom plate 22 of the housing 20. When the tension spring is adopted, the elastic force of the cup holder assembly 10 sliding from the second set position to the first set position can be provided through the stretching deformation of the tension spring.

Of course, the drive mechanism 50 may employ a pneumatic cylinder, such as a cylinder body of a pneumatic cylinder, secured to the base 22, with the piston rod of the pneumatic cylinder fixedly coupled to the cup holder assembly 10, in addition to the resilient member of the above example. The cylinder body is open at one end facing away from the storage bin, and the piston rod extends out of the opening and is fixedly connected with the cup holder assembly 10. When the cup holder assembly 10 slides from the second set position to the first set position, the piston of the piston rod is pulled, and the air pressure of the air enclosed by the piston is reduced, so that negative pressure is formed. Thus, when the cup holder assembly 10 slides from the second set position to the first set position, the cup holder assembly 10 can be pushed to slide by the pressure difference on both sides of the piston.

When the cup holder assembly 10 is driven to slide out by the driving mechanism 50, the driving mechanism 50 is driven in a unidirectional manner, so that the cup holder assembly 10 needs to be pushed by a hand to be hidden in the housing 20 when sliding into the housing 20.

When the driving mechanism 50 is specifically provided, the number of the driving mechanisms 50 may be one or two, three, or the like. As shown in fig. 2, the number of driving mechanisms 50 is two, and the two driving mechanisms 50 are arranged on opposite sides of the locking mechanism 30 in a first direction perpendicular to the sliding direction of the cup holder assembly 10. For convenience of description, the two driving mechanisms 50 are respectively named as a first driving mechanism 51 and a second driving mechanism 52. Referring to fig. 3, the first driving mechanism 51 and the second driving mechanism 52 are arranged at intervals along the first direction. When the other support component slides, the first driving mechanism 51 and the second driving mechanism 52 synchronously drive, so that the stability of the cup support component 10 during sliding is improved.

When the cup holder assembly 10 is not required to carry a cup holder, it is required to be held in the second set position. In particular locking, the cup holder assembly 10 is locked in the second set position by the locking mechanism 30. The locking mechanism 30, when provided, is disposed with the drive mechanism 50 on a side of the cup holder assembly 10 facing away from the opening of the storage bin. That is, the gap between the cup holder assembly 10 and the bottom plate 22 of the housing 20 is utilized to fully utilize the space in the housing 20, reduce the size of the exposed gap between the housing 20 and the cup holder assembly 10, and improve the appearance effect of the auxiliary instrument panel assembly.

With continued reference to fig. 2 and 3, the locking mechanism includes an elastic tab 32 and a labyrinth guide 31. Wherein the resilient tab 32 is disposed on the cup holder assembly 10, such as the resilient tab 32 is secured to the base 12 of the cup holder assembly 10. And labyrinth guide 31 is provided on bottom plate 22 of housing 20. The resilient tab 32 slides synchronously within the labyrinth guide 31 as the cup holder assembly 10 slides relative to the housing 20. When the cup holder assembly 10 is slid to the second setting position, the resilient tab 32 is locked with the labyrinth guide 31, thereby locking the cup holder assembly 10 in the second setting position.

First, the labyrinth guide 31 will be described in detail, and the labyrinth guide 31 includes a groove 311 formed in the bottom plate 22 of the housing 20, and the longitudinal direction of the groove 311 is along the sliding direction of the cup holder assembly 10. The guide block 313 and the locking block 312 are disposed in the groove 311, and the guide block 313 and the locking block 312 are disposed at intervals along the sliding direction of the cup holder assembly 10 when being arranged. Wherein the guide block 313 is located at an end near the storage bin and the locking block 312 is located at an end far from the storage bin. The locking block 312 is configured to cooperate with the resilient tab 32 to lock the same, such that a locking notch 3121 is provided at an end of the locking block 312 facing away from the storage compartment. When the elastic piece 32 slides to the locking piece 312, the elastic piece 32 can be locked by the locking notch 3121.

The guide block 313 and the lock block 312 divide the groove body 311 into a first guide rail b and a second guide rail a intersecting in an X-shape. During the sliding of the elastic sheet 32, the elastic sheet 32 slides alternately in the first guide rail b and the second guide rail a.

When the cup holder assembly 10 is slid from the first set position to the second set position, the resilient tab 32 slides along the first guide track b to the locking notch 3121 and locks. When the cup holder assembly 10 is slid from the second setting position to the first setting position, the elastic piece 32 slides out of the locking notch 3121 and slides along the second guide rail a to an end of the second guide rail a near the storage bin. Thereby effecting locking and unlocking of the cup holder assembly 10. Specifically, when the elastic piece 32 moves to the second guide rail a, a side wall of the groove body 311 opposite to the locking notch 3121 is a guide side wall for guiding the elastic piece 32 to the second guide rail a.

To facilitate an understanding of the locking and unlocking of the cup holder assembly 10, the overall operation is described in detail below in conjunction with the drive mechanism 50 and the locking mechanism 30. When the cup holder assembly 10 slides out of the housing 20, the cup holder assembly 10 first needs to be unlocked. At the time of specific unlocking, it is required that the user continues to push the cup holder assembly 10 into the housing 20, and the elastic piece 32 is guided to the second guide rail a by the guide sidewall. When the user releases the push on the cup holder assembly 10, the drive mechanism 50 pulls the cup holder assembly 10 from the second setting position to the first setting position. At the same time, the elastic piece 32 moves under the guide of the second guide rail a formed by the side wall of the groove body 311, the locking block 312, and the guide block 313. When the cup holder assembly 10 slides into the housing 20, the user is required to push the cup holder assembly 10, meanwhile, the elastic piece 32 slides in the first guide rail b formed by the guide block 313, the side wall of the groove body 311 and the locking block 312, and when the elastic piece 32 moves to the end side walls of the locking block 312 and the groove body 311, the elastic piece 32 enters the outside of the locking notch 3121 through the elastic force of the elastic piece 32, and when the user withdraws the external force, the driving mechanism 50 pulls the cup holder assembly 10, and the elastic piece 32 slides into the locking notch 3121 to lock the cup holder assembly 10.

As can be seen from the above description, the automatic ejection of the cup holder assembly 10 and the manual pushing of the cup holder assembly can be achieved by the cooperation of the driving mechanism 50 and the locking mechanism 30. The whole device has simple structure and is convenient for the user to operate.

When the labyrinth guide 31 is specifically provided, the labyrinth guide 31 is located between the first driving mechanism 51 and the second driving mechanism 52, so that the cup holder assembly 10 can be more stable in movement.

With continued reference to fig. 2 and 3, the cup holder mechanism provided by the embodiments of the present application further includes a damping assembly 40, the damping assembly 40 being configured to allow the cup holder assembly 10 to be more stable when slid. The damper assembly 40 includes a damper rack 41 and a damper gear 42 engaged with the damper rack 41. Wherein, the damping rack 41 is disposed at the bottom plate 22 of the housing 20, and the length direction of the damping rack 41 is along the sliding direction of the cup holder assembly 10. While the damper gear 42 is rotatably coupled to the cup holder assembly 10, the damper gear 42 may be specifically disposed on the base 12 of the cup holder assembly 10. I.e. the damping assembly 40 is also located on the side of the cup holder assembly 10 facing away from the opening of the storage bin. So that the damper assembly 40 can be hidden under the cup holder assembly 10. When the cup holder assembly 10 slides, the damping gear 42 rotates on the damping rack 41 and provides a damping force to the cup holder assembly 10 so that the cup holder assembly 10 can slide out more stably when sliding out.

When the damper rack 41 is specifically provided, the damper rack 41 is also located between the first drive mechanism 51 and the second drive mechanism 52. Such that the damping force provided is between the driving forces provided by the two driving mechanisms 50 so that the cup holder assembly 10 can slide out more stably.

According to the scheme, the auxiliary instrument board assembly provided by the embodiment of the application adopts the mode that the cup holder assembly 10 is arranged in a sliding way, and when the cup holder assembly 10 is not used, the auxiliary instrument board assembly can be hidden in the shell 20, so that the bearing space of the storage bin can be changed, in addition, the automatic ejection of the cup holder assembly 10 can be realized through the cooperation of the driving mechanism 50 and the locking mechanism, and the position of the cup holder assembly 10 can be conveniently adjusted.

It should be noted that the auxiliary instrument panel assembly provided by the embodiment of the present application is not limited to the specific structure of the above example, and any solution that adopts the above concept to improve the storage compartment of the auxiliary instrument panel assembly is within the scope of the embodiment of the present application.

The embodiment of the application also provides an automobile, which comprises an automobile body and any auxiliary instrument board assembly fixed on the automobile body. In the above technical scheme, by adopting the manner that the cup holder assembly 10 is slidably arranged, when the cup holder assembly 10 is not used, the cup holder assembly 10 can be hidden in the shell 20, so that the bearing space of the storage bin can be changed, in addition, the cup holder assembly 10 can be automatically ejected through the cooperation of the driving mechanism 50 and the locking mechanism, and the position of the cup holder assembly 10 can be conveniently adjusted.

The present disclosure is intended to embrace all such alternatives, modifications and variances which fall within the broad scope of the appended claims. Any omissions, modifications, equivalents, improvements, and the like, which are within the spirit and principles of the one or more embodiments of the disclosure, are therefore intended to be included within the scope of the disclosure.

The foregoing is merely illustrative embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about variations or substitutions within the technical scope of the present application, and the application should be covered. Therefore, the protection scope of the application is subject to the protection scope of the claims.

Claims (10)

1. A sub fascia console assembly, comprising: an assembly housing and a cup holder mechanism;

the assembly shell encloses a storage bin with an opening;

The cup holder mechanism comprises a shell fixed in the assembly shell and a cup holder assembly slidingly assembled in the shell; when the cup holder assembly slides to a first set position, the cup holder assembly is exposed in the storage bin; when the cup holder assembly slides to a second set position, the cup holder assembly is hidden into the assembly housing;

The cup stand mechanism further comprises a driving mechanism and a locking mechanism; wherein, the driving mechanism and the locking mechanism are positioned at one side of the cup holder assembly, which is away from the opening of the storage bin;

the driving mechanism is used for driving the cup holder assembly to slide from the second setting position to the first setting position;

The locking mechanism comprises an elastic sheet arranged on the cup holder assembly and a labyrinth guide rail arranged on the bottom plate of the shell; when the cup holder assembly slides to the second setting position, the elastic piece is locked with the labyrinth guide rail, and the cup holder assembly is locked at the second setting position.

2. The instrument cluster assembly of claim 1, wherein the drive mechanism is an elastic member and the elastic member drives the cup holder assembly to slide from the second set position to the first set position by an elastic force.

3. The sub fascia assembly of claim 2, wherein said drive mechanism is a coil spring; one end of the coil spring is fixedly connected with the bottom plate of the shell, and the other end of the coil spring is fixedly connected with the cup holder assembly.

4. The sub fascia assembly according to claim 3, wherein said cup holder assembly comprises a cup holder body and a base fixedly coupled to said cup holder body; wherein,

The cup stand body is connected with the shell in a sliding way; one end of the coil spring is fixedly connected with the base, and the elastic sheet is fixedly connected with the base.

5. The instrument cluster assembly of claim 4, wherein the cup holder body is fixedly coupled to the base by a threaded connection.

6. The instrument cluster assembly of claim 1 wherein the number of drive mechanisms is two and the two drive mechanisms are aligned on opposite sides of the locking mechanism in a first direction; wherein,

The first direction is perpendicular to a sliding direction of the cup holder assembly.

7. The fascia console assembly of claim 1, wherein the cup holder mechanism further comprises a damping assembly comprising a damping rack disposed at the floor of the housing, and a damping gear engaged with the damping rack;

The damping gear is rotationally connected with the cup stand assembly;

the length direction of the damping rack is along the sliding direction of the cup holder assembly.

8. The sub instrument panel assembly according to any one of claims 1 to 7, wherein the labyrinth guide rail comprises a groove body formed in a bottom plate of the housing, and a guide block and a locking block arranged in the groove body; wherein,

The length direction of the groove body is along the sliding direction of the cup holder assembly, and the guide blocks and the locking blocks are arranged at intervals along the sliding direction of the cup holder assembly; the locking block is positioned at one end far away from the storage bin; one end of the locking block, which is away from the storage bin, is provided with a locking notch;

The guide block and the locking block divide the groove body into a first guide rail and a second guide rail which are crossed in an X shape;

When the cup holder assembly slides from a first setting position to a second setting position, the elastic piece slides to the locking notch along the first guide rail and is locked;

When the cup holder assembly slides from the second setting position to the first setting position, the elastic piece slides out of the locking notch and slides along the second guide rail to one end of the second guide rail, which is close to the storage bin.

9. The instrument cluster assembly of claim 8 wherein the housing has guide rails on opposite side walls and the cup holder assembly has a slide block slidably engaged with each guide rail.

10. An automobile comprising a body and a sub-fascia assembly according to any one of claims 1 to 9 secured to the body.