CN215398526U - Chip type customized switch assembly capable of randomly changing switch positions - Google Patents

Abstract

The utility model relates to a chip type customized switch assembly with switch positions capable of being changed randomly, which comprises an installation frame and a plurality of function switches, wherein the installation frame is provided with a plurality of installation positions for installing the function switches, the installation frame is provided with a main circuit board, each function switch is provided with a function circuit board, the main circuit board is provided with a controller and an assembly interface, the main circuit board is respectively provided with a first connector corresponding to each installation position, the assembly interface and each first connector are respectively connected with the controller, each function circuit board is provided with a second connector matched with the first connector, and each function circuit board is provided with a memory chip. Adopt above-mentioned scheme, provide an accessible driver self custom hobby with different function switch assembly to the different installation position of installation frame, later with the installation frame assembly in the vehicle realize the switch position's can be changed wantonly to the chip customization of the best driving impression of function switch operation switch assembly.

Description

Chip type customized switch assembly capable of randomly changing switch positions

Technical Field

The utility model relates to a chip type customized switch assembly with switch positions capable of being changed randomly.

Background

The function switch is one of common carrying parts of the automobile, is large in quantity, is adapted to be carried on automobile models such as heavy-duty commercial vehicles and the like, is widely distributed and covers various operation functions of the automobile, such as front and rear fog lamps, light adjustment, backlight adjustment, working lamp control, indoor illuminating lamps, driver reading lamps, ASR cancellation, ESC cancellation, hydraulic turnover, horn conversion, inter-axle differential locks, inter-wheel differential locks, left glass lifter switches, right glass lifter switches, skylight control switches, slope starting auxiliary switches, climbing modes, low-speed modes, auxiliary brake cancellation, AEBS cancellation, LDW cancellation, FCW cancellation, power control main switches, fuel change-over switches, fuel heating switches, floating bridge lifting, driving assistance, ECAS second height, power takeoff, parking power takeoff and the like, and can reach more than 100 function switches for preliminary statistics.

Since the functions of different vehicles are different, the number and positions of the function switches are adapted to the corresponding vehicle.

The problem that function switch exists in current vehicle lies in: design position of each function switch in current vehicle is decided by the vehicle design, and the position can't be changed, when the whole design of vehicle promptly, according to popular operation custom, the most masses operation of adaptation more comes for the fitting position that each function switch design corresponds, but, because there is individual difference in different drivers, like difference such as height, hand length, control with the hand custom, different function switch frequencies of use, consequently, the function switch that the same position will appear has different driving feelings to different drivers, can't realize different drivers's best driving sensation.

Therefore, how to achieve the optimal driving feeling for the same driving vehicle by different drivers becomes a problem to be solved urgently by those skilled in the art.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a chip type customized switch assembly with the switch position capable of being changed randomly, wherein different function switches can be assembled to different installation positions of an installation frame through the habit and preference of a driver, and then the installation frame is assembled on a vehicle to realize the optimal driving feeling of the function switch operation.

In order to achieve the purpose, the utility model provides the following technical scheme: including installation frame and a plurality of function switch, be provided with the installation position of a plurality of confession arbitrary function switch installations on the installation frame, be provided with total circuit board on the installation frame, each be provided with the function circuit board on the function switch, be provided with controller, assembly interface on the total circuit board, total circuit board corresponds each installation position and is provided with first connector respectively, assembly interface and each first connector are connected with the controller respectively, each be provided with the second connector with first connector adaptation on the function circuit board, each be provided with memory chip on the function circuit board.

The utility model is further configured to: the memory chip adopts EEPROM.

The utility model is further configured to: the number of the installation positions is 2-10.

The utility model is further configured to: each installation position is arranged along the horizontal direction, each installation position is provided with an installation slot, the upper end of each installation slot penetrates through the installation frame and is provided with an insertion hole, each function switch comprises an installation part and a control part, when the function switch is installed on the installation position, the installation part is located in the installation slot, and the control part is located above the insertion hole.

The utility model is further configured to: each the installation position is located the horizontal both sides of corresponding installation slot and is provided with the joint groove respectively, and the opposite direction in two joint grooves that correspond all is along the both ends of the opposite direction in two joint grooves that correspond and runs through the installation frame setting with the array orientation mutually perpendicular of installation position, each the horizontal both sides of installation department are provided with first joint piece respectively, each first joint piece lower extreme fixed mounting in installation department, each first joint piece is along vertical direction slope of keeping away from the direction of installation department along the level gradually up.

The utility model is further configured to: the installation frame periphery is provided with the second joint piece, second joint piece lower extreme fixed mounting is in the installation frame, the second joint piece is followed vertical direction slope of keeping away from the installation frame gradually along the level up, be provided with the dismouting piece on the installation frame, the dismouting piece is installed in the installation frame along vertical sliding, the top that the dismouting piece is located the installation frame is provided with and is used for driving the vertical drive portion that slides of dismouting piece and is located second joint piece below and is provided with the linkage portion that is used for driving the upset of second joint piece, the dismouting piece is located the movement track of linkage portion.

The utility model is further configured to: the quantity of second joint piece and dismouting piece is two, and sets up respectively in the installation frame along the both sides of installation position array direction.

The utility model is further configured to: all or part of the function switches comprise a shell, shifting blocks, a gear block and a gear spring, wherein each shifting block is hinged to the shell, the shifting blocks and the hinged shaft of the shell are horizontally arranged, each gear block is slidably arranged on the shell, the sliding direction of each gear block is perpendicular to the hinged shaft of each shifting block and the shell, each gear spring is used for extruding the gear block towards the shifting blocks, a first working surface and a second working surface are arranged on two sides of each shifting block, the opposite directions of the first working surface and the second working surface are perpendicular to the hinged shaft of each shifting block and the shell and the sliding direction of each gear block respectively, the gear block is positioned on the motion tracks of the first working surface and the second working surface, and when the gear block is positioned on the first working surface, the included angle between the direction in which the gear block slides towards the shifting blocks and the direction parallel to the first working surface and the second working surface is greater than or equal to 90 degrees or smaller than 90 degrees, when the gear block is positioned on the second working surface, the included angle between the direction of the gear block sliding towards the shifting block and the direction parallel to the second working surface and towards the first working surface is more than or equal to 90 degrees or less than 90 degrees.

The utility model is further configured to: and each shifting block is positioned between the first working surface and the second working surface and is provided with a positioning clamping groove for clamping and positioning the stop block.

The utility model is further configured to: a first functional light-emitting cavity, a main light-emitting cavity and a second functional light-emitting cavity are sequentially arranged in all or part of the shell along the horizontal direction, and the arrangement direction of the first functional light-emitting cavity, the main light-emitting cavity and the second functional light-emitting cavity is vertical to the hinge axis of the shifting block and the shell, a first function lamp is arranged in the first function light-emitting cavity, a main light-emitting lamp is arranged in the main light-emitting cavity, the shell is arranged between the corresponding first functional light-emitting cavity and the main light-emitting cavity and between the corresponding second functional light-emitting cavity and the main light-emitting cavity, and the shifting blocks are arranged between the corresponding first functional light-emitting cavity and the main light-emitting cavity and between the corresponding second functional light-emitting cavity and the main light-emitting cavity and are provided with turnover light-blocking plates.

By adopting the technical scheme, 1, through arranging the installation frame (the installation frame is used for being installed on the vehicle) and arranging a plurality of installation positions on the installation frame, so that the driver can sort the function switches on the installation positions through the driving habit of the driver to achieve the best driving feeling, after the sorting is finished, the second connector corresponding to each function switch is connected with the first connector of the corresponding installation position, therefore, the memory chip of the corresponding function switch (different signals are stored in the memory chips of the function switches with different functions) can be identified by the controller for determining the actual function of the function switch, therefore, the function switch is driven, the controller can generate a signal corresponding to the function switch and transmit the signal to the vehicle to operate corresponding functions, and the function switch is exchanged without influencing the accurate control of the function switch on the vehicle; 2. the setting of assembly interface for installation frame and vehicle only need single interface alright realize being connected, not only make the dismouting more convenient, greatly reduced the wiring moreover, make vehicle wiring structure more succinct.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is an assembly view of an embodiment of the present invention;

FIG. 2 is a circuit diagram of an embodiment of the present invention;

FIG. 3 is an exploded view of an embodiment of the present invention;

FIG. 4 is a cross-sectional view of a mounting frame in an embodiment of the present invention;

FIG. 5 is an assembly view of a function switch in accordance with an embodiment of the present invention;

FIG. 6 is an exploded view of a function switch in accordance with an embodiment of the present invention;

FIG. 7 is a cross-sectional view of an embodiment of the present invention;

FIG. 8 is an enlarged view of A in FIG. 7;

FIG. 9 is an enlarged view of a portion of FIG. 4;

FIG. 10 is a cross-sectional view of a functional switch in accordance with an embodiment of the present invention;

FIG. 11 is a cross-sectional view of a functional switch in accordance with an embodiment of the present invention;

FIG. 12 is a component diagram of a functional circuit board in accordance with an embodiment of the present invention;

FIG. 13 is a schematic view of one of the dials according to the embodiment of the present invention;

FIG. 14 is a schematic view of one of the dials according to the embodiment of the present invention;

FIG. 15 is a schematic view of one of the dials according to the embodiment of the present invention;

fig. 16 is a schematic diagram of one of the blocks according to the embodiment of the present invention.

1. A mounting frame; 11. an installation position; 12. a second clip piece; 111. installing a slot; 112. an insertion opening; 113. a clamping groove; 2. a function switch; 21. an installation part; 22. a control unit; 23. a first clip piece; 24. a housing; 25. shifting blocks; 26. a conductive rubber; 27. a slider; 28. a stop block; 29. a gear spring; 241. a first functional light emitting cavity; 242. a primary light emitting cavity; 243. a second functional light-emitting cavity; 244. fixing a light barrier; 251. a first working surface; 252. a second working surface; 253. positioning the clamping groove 254, turning over the light barrier; 3. a main circuit board; 31. an assembly interface; 32. a first connector; 4. a functional circuit board; 41. a second connector; 42. conducting the metal sheet; 43. a first function lamp; 44. a main light emitting lamp 45, a second function lamp; 5. disassembling the parts; 51. a drive section; 52. an interlocking part.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-6, the present invention discloses a chip-type customized switch assembly with switch positions capable of being changed arbitrarily, which comprises a mounting frame 1 and a plurality of function switches 2, wherein the mounting frame 1 is provided with a plurality of mounting positions 11 for mounting the function switches 2, so that each function switch 2 can be mounted at any mounting position 11, the mounting frame 1 is mounted on a vehicle together with the function switches 2 to realize the whole vehicle assembly, in addition, the mounting frame 1 is provided with a main circuit board 3, and each function switch 2 is provided with a function circuit board 4, wherein the main circuit board 3 is provided with a controller (the controller adopted in this embodiment is a single chip microcomputer MCU), an assembly interface 31 (LIN) and a power circuit, furthermore, the main circuit board 3 is provided with a first connector 32 corresponding to each mounting position 11, and the assembly interface 31 (LIN) and each first connector 32 are connected with the controller respectively, correspondingly, each functional circuit board 4 is provided with a second connector 41 adapted to the first connector 32, and each functional circuit board 4 is provided with a memory chip IC.

Therefore, a driver can sequence the function switches 2 on the installation positions 11 through the driving habit of the driver to achieve the best driving feeling, after the sequencing is completed, the second connector 41 corresponding to each function switch 2 is connected with the first connector 32 of the corresponding installation position 11, therefore, the controller MCU reads the storage signals in the memory chip IC through SCL and SDA, realizes the identification of the memory chip IC of the corresponding function switch 2 (different signals are stored in the memory chip IC of the function switches 2 with different functions) for determining the actual function of the function switch 2, so that when the function switch 2 is driven, the controller MCU will generate the signal corresponding to the function switch 2 and transmit the signal to the vehicle from the assembly interface 31 (LIN) for the operation of the corresponding function, realizes the position exchange of the function switch 2 and does not affect the precise control of the function switch 2 on the vehicle, in addition, an installation frame 1 only has an assembly interface 31 (LIN) for installation frame 1 only needs single interface alright realization with the vehicle to be connected, not only makes the dismouting more convenient, has greatly reduced the wiring moreover, makes vehicle wiring structure more succinct.

In this embodiment, the assembly interface 31 (LIN), each first connector 32, and each second connector 41 may adopt a pin or a socket, and the assembly interface 31 (LIN) of this embodiment adopts a pin, each first connector 32 adopts a socket, and each second connector 41 adopts a pin, so that the connection manner is more convenient.

Preferably, the memory chip in this embodiment adopts an EEPROM, so that the memory chip can effectively store data after power failure to ensure the stability of the identification of the function switch 2, and can be electrically erasable and programmable, so that different signals can be embedded as different function switches 2 as required before production, thereby improving the adaptability and greatly reducing the production cost, and in addition, the EEPROM can store 1 to 1024 bytes and can generate 1024 different storage signals, thereby effectively satisfying the existing 100 different function switches 2 differentiation and ensuring the full coverage differentiation.

Preferably, the number of the installation positions 11 in the embodiment is 2-10, and the mechanical structure part of the embodiment adopts 10 installation as a structure.

Referring to fig. 7 and 8, the installation positions 11 in the present embodiment are arranged in a left-right direction, wherein each installation position 11 is provided with a square installation slot 111, the upper end of each installation slot 111 penetrates through the installation frame 1 to be provided with an insertion hole 112, correspondingly, each function switch 2 comprises an installation portion 21 and a control portion 22, when the function switch 2 is installed at the installation position 11, the installation portion 21 is located in the installation slot 111, and the control portion 22 is located above the insertion hole 112, therefore, the installation portion 21 is inserted into the installation slot 111 to realize convenient and fast fixing and installation of the function switch 2 at the corresponding installation position 11, after the installation is completed, since the control portion 22 is located above the insertion hole 112 to realize exposure, the driver can operate through the control portion 22, and when the function switch 2 needs to be detached from the corresponding installation position 11, the driver can pull the function switch 2 upwards by bare hand, the disassembly is convenient, the convenience of changing the keys of the function switch 2 is greatly improved, the operation is more adaptive to the direct operation of a driver, and the best driving feeling is achieved.

In addition, in the embodiment, the mounting positions 11 are respectively provided with a clamping groove 113 at the front side and the rear side of the corresponding mounting slot 111, and each clamping groove 113 penetrates through the mounting frame 1 along the front-rear direction, correspondingly, the front side and the rear side of each mounting portion 21 are respectively provided with a first clamping sheet 23 made of metal elastic material, wherein the lower end of each first clamping sheet 23 is clamped and fixed on the mounting portion 21 to realize the mounting with the mounting portion 21, and in addition, each first clamping sheet 23 is inclined upwards along the vertical direction gradually along the direction away from the mounting portion 21 horizontally, so that in the process of inserting the mounting portion 21 into the mounting slot 111, the first clamping sheets 23 at the front side and the rear side are limited by the periphery of the insertion opening 112 and shrink towards the mounting portion 21, and after the mounting portion 21 completely enters the mounting slot 111, the first clamping sheets 23 are reset to enter the clamping grooves 113 to realize the clamping limitation of the mounting portion 21 and the mounting slot 111, function switch 2 can't be extracted up, realize installing in installation position 11 that function switch 2 is more stable, thereby prevent that function switch 2 from appearing the problem that drops from installation position 11 in the use, and if need dismantle function switch 2, driver's accessible finger drives two first joint pieces 23 simultaneously and is close to the shrink of installation department 21, make two first joint pieces 23 deviate from corresponding joint groove 113 jointly, later alright extract function switch 2 up and realize dismantling.

Referring to fig. 9, the mounting frame 1 of the present embodiment is provided with a second engaging piece 12 at the periphery, wherein the lower end of the second engaging piece 12 is fixedly mounted on the mounting frame 1 by integral molding, and the second engaging piece 12 is inclined upwards in the vertical direction gradually along the direction away from the mounting frame 1, correspondingly, the mounting frame 1 is provided with a detachable piece 5, wherein the detachable piece 5 is slidably mounted on the mounting frame 1 in the vertical direction by penetrating, and furthermore, the detachable piece 5 is provided with a driving portion 51 for driving the detachable piece 5 to slide vertically above the mounting frame 1 and a linking portion 52 for driving the second engaging piece 12 to turn over below the second engaging piece 12, and the detachable piece 5 is located on the movement track of the linking portion 52, so that the mounting frame 1 can be completely inserted into the vehicle and can be fastened to the vehicle by the second engaging piece 12 inclining in the direction away from the mounting frame 1, the installation frame 1 is fixedly installed on the vehicle, after the installation is finished, because the installation part 21 is positioned in the installation frame 1, namely, the installation part 21 is positioned in the vehicle, when the installation frame 1 is not detached from the vehicle, the function switch 2 cannot be detached from the installation frame 1, the detachment of the function switch 2 is further limited, the loss of the key function caused by the random detachment of the function switch 2 is prevented, in addition, if the function switch 2 needs to be replaced, the detaching piece 5 is pulled upwards through the driving part 51, the linkage part 52 is synchronously driven to move upwards to press the second clamping piece 12 through the linkage part 52, the second clamping piece 12 is enabled to approach towards the installation frame 1 to remove the installation with the vehicle, after the installation frame 1 is detached from the vehicle, the replacement, disassembly and assembly of the function switch 2 can be performed, in addition, if the installation frame 1 with the same number of linkages on the vehicle (namely, a plurality of installation frames 1 are arranged on the vehicle, and the number of the mounting positions 11 on the mounting frame 1 is the same), the positions of the two mounting frames 1 can be directly changed after the two mounting frames 1 are disassembled, and the function switches 2 on the two mounting frames 1 do not need to be disassembled and exchanged.

Preferably, the number of the second engagement pieces 12 and the number of the detachable pieces 5 in this embodiment are two, and the second engagement pieces 12 and the detachable pieces 5 are respectively disposed on the left and right sides of the mounting frame 1, so that the second engagement pieces 12 and the detachable pieces 5 are disposed on both sides of the arrangement direction of the mounting locations 11 (the length direction of the mounting frame 1) to achieve the best limiting effect by using the least limiting points.

Wherein, the function switches 2 in this embodiment are various in types, and can adopt touch switches, button switches, rocker switches, etc., as shown in fig. 10-12, the function switches 2 in this embodiment all adopt rocker switches, wherein, each function switch 2 includes a housing 24, a shifting block 25, a conductive rubber 26, a sliding block 27, a stop block 28 and a stop spring 29, the left and right sides of each housing 24 are provided with a cylindrical protruding block in a protruding manner, so that the corresponding shifting block 25 is hinged with the cylindrical protruding block to the housing 24, thereby performing tilting forward and backward, wherein, the number of the sliding blocks 27 is two, the two sliding blocks 27 are all arranged in the housing 24, and the two sliding blocks 27 are symmetrically arranged forward and backward, in addition, the two sliding blocks 27 are both mounted on the housing 24 in a sliding manner along the vertical direction, and when the shifting block 25 tilts forward, the sliding block 27 on the front side can be driven to slide downward, and when tilting backward, the rear slide blocks 27 can be driven to slide downwards, wherein the conductive rubber 26 is arranged below each slide block 27, the functional circuit board 4 is arranged below the conductive rubber 26, and the front and rear sides of the upper end of the functional circuit board 4 are respectively provided with a conductive metal sheet 42, so that the slide block 27 on the front side slides downwards, the conductive rubber 26 is driven to move downwards to contact the conductive metal sheet 42 on the front side of the conductive functional circuit board 4 to generate a conductive signal, the slide block 27 on the rear side slides downwards to drive the conductive rubber 26 to move downwards to contact the conductive metal sheet 42 on the rear side of the conductive functional circuit board 4 to generate a conductive signal, wherein the stopper block 28 is arranged on the shell 24 in a vertical sliding manner in a circumferential limiting manner, wherein the stopper spring 29 is arranged between the stopper block 28 and the shell 24 in a compression manner, the upper end of the stopper spring 29 abuts against the stopper block 28, and the lower end abuts against the shell 24, under the action of the shift spring 29, the shift block 28 is driven upwards and abuts against the lower end of the shift block 25, in addition, the lower end of the shift block 25 is positioned at the front side and the rear side of the shift block 28 and is respectively provided with a first working surface 251 and a second working surface 252, when the shift block 25 tilts forwards, the first working surface 251 is overturned to be in contact with the shift block 28, when the shift block 25 tilts backwards, the second working surface 252 is overturned to be in contact with the shift block 28, wherein, the first working surface 251 and the second working surface 252 on the shift block 25 are combined in 4, which are respectively shown in figures 13-16, when the shift block 28 is positioned on the first working surface 251 in the condition shown in figure 13, the included angle between the upward direction of the shift block 28 and the direction parallel to the first working surface 251 and towards the second working surface 252 is smaller than 90 degrees, so that the shift block 25 automatically resets after the external force is removed, when the shift block 28 is positioned on the second working surface 252, the angle between the upward direction of the stop block 28 and the direction parallel to the second working surface 252 and facing the first working surface 251 is greater than or equal to 90 degrees, so that the shift block 25 cannot be reset after the external force is removed, in the case shown in fig. 14, when the stop block 28 is located on the first working surface 251, the angle between the upward direction of the stop block 28 and the direction parallel to the first working surface 251 and facing the second working surface 252 is greater than or equal to 90 degrees, so that the shift block 25 cannot be reset after the external force is removed, when the stop block 28 is located on the second working surface 252, the angle between the upward direction of the stop block 28 and the direction parallel to the second working surface 252 and facing the first working surface 251 is less than 90 degrees, so that the shift block 25 automatically resets after the external force is removed, in the case shown in fig. 13 and 14, a case of single-side self-locking and single-side self-resetting is adopted, in the case shown in fig. 15, when the stop block 28 is located on the first working surface 251, when the block 28 is located on the second working surface 252, the angle between the upward direction of the block 28 and the direction parallel to the second working surface 251 and facing the first working surface 251 is greater than or equal to 90 degrees, when the block 28 is located on the second working surface 252, the angle between the upward direction of the block 28 and the direction parallel to the second working surface 252 and facing the first working surface 251 is less than 90 degrees, so that the block 25 automatically resets after the external force is removed, fig. 15 is a case of double-sided self-resetting, when the block 28 is located on the first working surface 251, the angle between the upward direction of the block 28 and the direction parallel to the first working surface 251 and facing the second working surface 252 is greater than or equal to 90 degrees, so that the block 25 cannot reset after the external force is removed, when the block 28 is located on the second working surface 252, the angle between the upward direction of the block 28 and the direction parallel to the second working surface 252 and facing the first working surface 251 is greater than or equal to 90 degrees, the shifting block 25 can not reset after the external force is removed, and fig. 16 shows the condition of double-side self-locking, so that the functional switches 2 with different operation modes can be realized by adopting different types of shifting blocks 25, and the operation diversity is improved.

Preferably, a positioning slot 253 for clamping and positioning the stop block 28 is arranged between the first working surface 251 and the second working surface 252 of each shift block 25 in the embodiment, so that when the shift block 25 is automatically or manually reset between the first working surface 251 and the second working surface 252, stable positioning is ensured by clamping the stop block 28 and the positioning slot 253.

In addition, in the present embodiment, a first function light-emitting cavity 241, a main light-emitting cavity 242 and a second function light-emitting cavity 243 are sequentially arranged in the housing 24 along the front-back direction, in addition, a first function lamp 43 is disposed in the first function light-emitting cavity 241, a main light-emitting lamp 44 is disposed in the main light-emitting cavity 242, a second function lamp 45 is disposed in the second function light-emitting cavity 243, and the first function lamp 43, the main light-emitting lamp 44 and the second function lamp 45 are disposed in the corresponding function circuit board 4, in addition, a fixed light-blocking plate 244 is disposed between the corresponding first function light-emitting cavity 241 and the main light-emitting cavity 242 and between the corresponding second function light-emitting cavity 243 and the main light-emitting cavity 242 of each housing 24, and a turning light-blocking plate 254 is disposed between the corresponding first function light-emitting cavity 241 and the main light-emitting cavity 242 and between the corresponding second function light-emitting cavity 243 and the main light-emitting cavity 242 of each dial 25, therefore, the two fixed light barriers 244 are used for mainly blocking the first functional light-emitting cavity 241, the main light-emitting cavity 242 and the second functional light-emitting cavity 243, so that the first functional lamp 43, the main light-emitting lamp 44 and the second functional lamp 45 do not generate light leakage phenomenon when emitting light in the respective cavities, and light leakage interference is prevented.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The utility model provides a chip type customization can change switch assembly of switch position wantonly which characterized in that: including installation frame and a plurality of function switch, be provided with the installation position of a plurality of confession arbitrary function switch installations on the installation frame, be provided with total circuit board on the installation frame, each be provided with the function circuit board on the function switch, be provided with controller, assembly interface on the total circuit board, total circuit board corresponds each installation position and is provided with first connector respectively, assembly interface and each first connector are connected with the controller respectively, each be provided with the second connector with first connector adaptation on the function circuit board, each be provided with memory chip on the function circuit board.

2. The chip-based customized switch assembly of claim 1, wherein the switch assembly comprises: the memory chip adopts EEPROM.

3. The chip-based customized switch assembly of claim 1, wherein the switch assembly comprises: the number of the installation positions is 2-10.

4. The chip-based customized switch assembly of claim 1, wherein the switch assembly comprises: each installation position is arranged along the horizontal direction, each installation position is provided with an installation slot, the upper end of each installation slot penetrates through the installation frame and is provided with an insertion hole, each function switch comprises an installation part and a control part, when the function switch is installed on the installation position, the installation part is located in the installation slot, and the control part is located above the insertion hole.

5. The chip-based customized switch assembly of claim 4, wherein the switch assembly comprises: each the installation position is located the horizontal both sides of corresponding installation slot and is provided with the joint groove respectively, and the opposite direction in two joint grooves that correspond all is along the both ends of the opposite direction in two joint grooves that correspond and runs through the installation frame setting with the array orientation mutually perpendicular of installation position, each the horizontal both sides of installation department are provided with first joint piece respectively, each first joint piece lower extreme fixed mounting in installation department, each first joint piece is along vertical direction slope of keeping away from the direction of installation department along the level gradually up.

6. A chip-based customized switch assembly of claim 4 or 5, wherein the switch assembly comprises: the installation frame periphery is provided with the second joint piece, second joint piece lower extreme fixed mounting is in the installation frame, the second joint piece is followed vertical direction slope of keeping away from the installation frame gradually along the level up, be provided with the dismouting piece on the installation frame, the dismouting piece is installed in the installation frame along vertical sliding, the top that the dismouting piece is located the installation frame is provided with and is used for driving the vertical drive portion that slides of dismouting piece and is located second joint piece below and is provided with the linkage portion that is used for driving the upset of second joint piece, the dismouting piece is located the movement track of linkage portion.

7. The chip-based customized switch assembly of claim 6, wherein the switch assembly comprises: the quantity of second joint piece and dismouting piece is two, and sets up respectively in the installation frame along the both sides of installation position array direction.

8. The chip-based customized switch assembly of claim 1, wherein the switch assembly comprises: all or part of the function switches comprise a shell, shifting blocks, a gear block and a gear spring, wherein each shifting block is hinged to the shell, the shifting blocks and the hinged shaft of the shell are horizontally arranged, each gear block is slidably arranged on the shell, the sliding direction of each gear block is perpendicular to the hinged shaft of each shifting block and the shell, each gear spring is used for extruding the gear block towards the shifting blocks, a first working surface and a second working surface are arranged on two sides of each shifting block, the opposite directions of the first working surface and the second working surface are perpendicular to the hinged shaft of each shifting block and the shell and the sliding direction of each gear block respectively, the gear block is positioned on the motion tracks of the first working surface and the second working surface, and when the gear block is positioned on the first working surface, the included angle between the direction in which the gear block slides towards the shifting blocks and the direction parallel to the first working surface and the second working surface is greater than or equal to 90 degrees or smaller than 90 degrees, when the gear block is positioned on the second working surface, the included angle between the direction of the gear block sliding towards the shifting block and the direction parallel to the second working surface and towards the first working surface is more than or equal to 90 degrees or less than 90 degrees.

9. The chip-based customized switch assembly of claim 8, wherein the switch assembly comprises: and each shifting block is positioned between the first working surface and the second working surface and is provided with a positioning clamping groove for clamping and positioning the stop block.

10. The chip-based customized switch assembly of claim 8, wherein the switch assembly comprises: a first functional light-emitting cavity, a main light-emitting cavity and a second functional light-emitting cavity are sequentially arranged in all or part of the shell along the horizontal direction, and the arrangement direction of the first functional light-emitting cavity, the main light-emitting cavity and the second functional light-emitting cavity is vertical to the hinge axis of the shifting block and the shell, a first function lamp is arranged in the first function light-emitting cavity, a main light-emitting lamp is arranged in the main light-emitting cavity, the shell is arranged between the corresponding first functional light-emitting cavity and the main light-emitting cavity and between the corresponding second functional light-emitting cavity and the main light-emitting cavity, and the shifting blocks are arranged between the corresponding first functional light-emitting cavity and the main light-emitting cavity and between the corresponding second functional light-emitting cavity and the main light-emitting cavity and are provided with turnover light-blocking plates.

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