CN113035606A

CN113035606A - Push knob controller

Info

Publication number: CN113035606A
Application number: CN202110326852.XA
Authority: CN
Inventors: 夏召祥; 孙斌斌; 许芳
Original assignee: Qingdao Yilai Intelligent Technology Co Ltd
Current assignee: Qingdao Yilai Intelligent Technology Co Ltd
Priority date: 2021-03-26
Filing date: 2021-03-26
Publication date: 2021-06-25
Anticipated expiration: 2041-03-26
Also published as: CN113035606B

Abstract

The invention relates to a push button controller which comprises an upper shell, a middle shell, a lower shell, a hollow encoder, a magnetic encoder, a key and a guide shell, wherein the middle shell is sleeved on the hollow encoder and fixedly connected with the outer ring of the hollow encoder, the guide shell is slidably arranged in the inner ring of the hollow encoder, the magnetic encoder comprises a magnet and a chip plate provided with a sensor, the magnet is arranged on the upper shell, the chip plate is fixedly arranged in the guide shell, the key is arranged on the lower shell, and the guide shell presses the key downwards. The depressible knob controller has the advantages that the structure of the controller is more compact through the assembly combination of the hollow encoder, the magnetic encoder and the keys, the product volume is reduced, the occupied desktop space is reduced, the upper shell can rotate and also be depressed, the middle shell can rotate, the control function is increased, and the problems of large structure volume and limited control function of the conventional double-knob controller are solved.

Description

Push knob controller

Technical Field

The present invention relates to a desktop controller for consumer electronics, and more particularly, to a depressible knob controller.

Background

Most desktop controllers on the current market only have one knob, the control forms are few, and complex control functions cannot be realized. The controller product of two knobs is very few, and few two knob products use two mechanical encoder to place with one heart mostly, and the volume of product is very big, occupies desktop space, rotates unstably, and user experience is not good, and control function is still comparatively limited moreover.

Disclosure of Invention

The invention provides a push button controller, which aims to solve the problems of large structural volume and limited control function of the conventional double-button controller.

In order to achieve the purpose, the invention adopts the technical scheme that:

a depressible knob controller comprising:

a lower housing;

a hollow encoder mounted on the lower case;

the middle shell is sleeved on the hollow encoder and connected with the outer ring of the hollow encoder so as to enable the outer ring to follow the hollow encoder;

the guide shell is arranged in an inner ring of the hollow encoder and moves up and down along the axial direction of the inner ring;

the key is arranged on the lower shell, and the guide shell presses the key when sliding downwards;

an upper housing rotatably mounted on the guide housing;

and a magnetic encoder installed on the upper case or in the guide case to measure a change in a magnetic field generated when the upper case rotates.

Preferably, the upper housing is mounted on a top plate of the guide housing, and the upper housing includes:

the lower surface of the top cover is in rolling contact with the roller pins in the mounting grooves formed in the top plate and is provided with a columnar structure, and the columnar structure penetrates through the mounting holes formed in the top plate;

and the gland is fixedly arranged on the columnar structure, and the upper surface of the gland is in rolling contact with the roller pin.

Preferably, the outer wall of the guide shell is provided with a buckle, the inner wall of the inner ring is provided with a limit groove, and the buckle is buckled in the limit groove to prevent the guide shell from being separated from the inner ring.

Preferably, a projection is arranged on the outer wall of the guide shell, a guide groove is axially arranged on the inner wall of the inner ring, and the projection is slidably mounted in the guide groove.

Preferably, the upper housing and the lower housing are both located inside the middle housing.

Preferably, an end surface of one end of the middle shell is flush with the upper surface of the upper shell, and an end surface of the other end of the middle shell is flush with the bottom surface of the lower shell.

Preferably, a return spring is installed between the guide housing and the lower housing, and the guide housing compresses the return spring when the key is pressed downward to generate an upward pushing force to push the guide housing to be separated from the key when the key is reset.

Preferably, the top of the lower shell is a main control board, and the button and the hollow encoder are both installed on the main control board.

Preferably, the lower shell is provided with a battery compartment for mounting a battery, and the conductive elastic sheet mounted on the main control board is positioned in the battery compartment;

and a cover plate is arranged on a filling port of the battery bin, and the cover plate presses and holds the battery on the conductive elastic sheet so that the battery supplies power to the main control board.

Preferably, a non-slip mat is mounted on the bottom surface of the lower case.

Preferably, the magnetic encoder includes a magnet and a chip board provided with a sensor, the magnet is mounted on the upper case, and the chip board is mounted in the guide case.

Preferably, the magnetic encoder includes a magnet and a chip board provided with a sensor, the magnet is installed in the guide housing, and the chip board is installed on the upper housing.

Compared with the prior art, the push button controller has the advantages that the structure of the controller is more compact, the product volume is reduced, the occupied desktop space is reduced, the upper shell can rotate or push, the middle shell can rotate, the control function is increased, and the problems of large structure volume and limited control function of the existing double-button controller are solved.

Drawings

FIG. 1 is an exploded view of a depressible knob controller according to the present invention;

FIG. 2 is a cross-sectional structural view of a depressible knob controller of the present invention;

in the above figures: 1. an upper housing; 11. a top cover; 12. a gland; 2. a middle shell; 3. a lower housing; 31. a main control board; 32 battery compartment; 33. a conductive spring plate; 34. a battery; 35. a cover plate; 4. a hollow encoder; 41. an inner ring; 42. an outer ring; 43. a limiting groove; 44. a guide groove; 5. a magnetic encoder; 51. a magnet; 52. a chip board; 6. pressing a key; 7. a guide housing; 71. a top plate; 72. mounting holes; 73. mounting grooves; 74. rolling needles; 75. buckling; 76. a bump; 77. a base plate; 8. a return spring; 9. a non-slip mat.

Detailed Description

The invention is described in detail below by way of exemplary embodiments. It should be understood, however, that elements, structures and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.

In the description of the present invention, it should be noted that the terms "inside", "outside", "upper", "lower", "front", "rear", and the like indicate orientations or positional relationships based on positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The depressible knob controller is used for solving the problems of unstable rotation and depression of a mechanical encoder type double-knob controller in the prior art, can greatly reduce the overall thickness of the controller, reduces the desktop space occupied by the controller and improves the user experience, and is explained in combination with specific embodiments below.

As shown in fig. 1 to 2, the present invention provides a depressible knob controller including an upper housing 1, a middle housing 2, a lower housing 3, a hollow encoder 4, a magnetic encoder 5, a key 6, and a guide housing 7. The hollow encoder 4 is fixedly arranged on the lower shell 3, and the hollow encoder 4 is provided with a fixed inner ring 41 and an outer ring 42 sleeved on the inner ring 41; the middle shell 2 is sleeved on the hollow encoder 4, the hollow encoder 4 is hidden and installed inside the middle shell 2, and the middle shell 2 is connected with an outer ring 42 of the hollow encoder 4; the guide housing 7 is mounted in the inner ring 41 of the hollow encoder 4 so as to be movable up and down in the axial direction of the inner ring 41; the key 6 is arranged on the lower shell 3 and is positioned below the guide shell 7; the upper shell 1 is rotatably arranged on the guide shell 7; the magnetic encoder 5 is mounted on the upper housing 1 or in a guide housing 7.

Wherein, the middle shell 2 is rotated, the outer ring 42 connected with the middle shell rotates, so that the hollow encoder 4 measures the angular displacement generated by the rotation of the middle shell 2 and controls the circuit electrically connected with the hollow encoder 2; rotating the upper shell 1 to generate a rotating magnetic field, measuring the change of the magnetic field by the magnetic encoder 5, measuring the angular displacement generated by the rotation of the upper shell 1, and controlling a circuit electrically connected with the magnetic encoder 5; the upper shell 1 is pressed, the guide shell 7 is pressed downwards, the guide shell 7 is further pressed downwards, the key 6 is further pressed downwards, and the key 6 controls a circuit electrically connected with the key.

The push-button controller, the magnetic encoder 5 and the push button 6 are positioned in the space inside the hollow encoder 4, the structure integration is stronger, the product volume is small, the occupation of the desktop space is reduced, the upper shell 1 can rotate and can also be pushed, the middle shell 2 can rotate, the control function is added, and the problems of large structure volume and limited control function of the existing double-button controller are solved.

In order to realize the rotary mounting of the upper housing 1, the top plate 71 of the guide housing 7 is provided with a mounting hole 72 and a mounting groove 73. The mounting hole 72 is positioned in the center of the top plate 71, and a plurality of mounting grooves 73 are radially arranged and are positioned on the same circumference with the mounting hole 72 as the center; the upper shell 1 comprises a top cover 11 and a gland 12 which are respectively positioned at the upper side and the lower side of a top plate 71; the lower surface of the top cover 11 is provided with a columnar structure 13, and the columnar structure 13 penetrates through the mounting hole 72 and is connected with the gland 12; the installation groove 73 is internally provided with a roller pin 74, and the lower surface of the top cover 11 and the upper surface of the gland 12 are in rolling contact with the roller pin 74.

Among them, the top plate 71 of the guide housing 7, the upper housing 1, and the needle rollers 74 constitute a simple needle roller bearing set, so that the upper housing 1 can be smoothly rotated, and further, circuit control is performed by the magnetic encoder 5.

In the present embodiment, in order to facilitate the installation of the magnetic encoder 5, the bottom plate 77 of the guide housing 7 is detachable, so that the inner space of the guide housing 7 is opened, and the magnetic encoder 5 and the pressing cover 12 are installed.

In the present embodiment, in order to firmly mount the guide housing 7 in the inner ring 41 of the hollow encoder 4, the outer wall of the guide housing 7 is provided with a snap 75, and the inner wall of the inner ring 41 of the hollow encoder 4 is provided with a limit groove 43. The clip 75 has elasticity, and when the guide housing 7 is installed in the inner ring 41 from bottom to top, the inner wall of the inner ring 41 pushes the clip 75 inward to slide against the wall. When the latch 75 moves to the stopper groove 43, it springs outward and snaps into the stopper groove 43. The stopper groove 43 has a certain length in the axial direction, and the catch 74 slides up and down in the stopper groove 43 when the guide housing 7 moves up and down. The limit groove 43 limits the vertical movement range of the buckle 75, so that the guide housing 7 cannot be separated from the inner ring 41 of the hollow encoder 4 upwards, and the structure is kept stable.

In the present embodiment, in order to ensure that the circuit control can be performed well when the upper housing 1 rotates, the outer wall of the guide housing 7 is provided with a projection 76, the inner wall of the inner ring 41 is provided with a guide groove 44 in the axial direction, and the projection 76 is slidably mounted in the guide groove 44. The guide groove 44 guides the up-and-down movement of the guide housing 7 through the bump 76, and limits the guide housing 7 to prevent the guide housing 7 from rotating, so that the guide housing 7 can not rotate synchronously when the upper housing 1 is rotated, the magnetic encoder 5 can accurately detect the angular displacement of the rotation of the upper housing 1, and the circuit can be accurately controlled when the upper housing 1 rotates.

In the present embodiment, in order to ensure the compactness of the structure, the upper housing 1 and the lower housing 3 are both located inside the middle housing 2, i.e. the upper housing 1 and the lower housing 3 are both mounted in the cylindrical middle housing 2 in a hidden manner, so that the height of the whole controller is reduced. In order to meet the requirement of compactness and ensure the convenience of use of the controller, the end face of one end of the middle shell 2 is flush with the upper surface of the upper shell 1, and the end face of the other end of the middle shell is flush with the bottom surface of the lower shell 3, so that the upper shell 1 is flush with the top end of the middle shell 2, the surface of the upper shell 1 can be exposed to the outside to the greatest extent while the upper shell 1 is installed inside the middle shell 2, and a user can press and rotate the controller conveniently; lower casing 3 and well casing 2's bottom parallel and level, when making the controller place on the desktop, casing 3 can fully laminate with the desktop down, and it remains static to produce sufficient frictional force, and well casing 2 can smoothly rotate, guarantees that hollow encoder 4 can accurately detect the rotatory angle displacement of well casing 2 to accurate control circuit.

In the present embodiment, in order to return the guide housing 7, a return spring 8 is installed between the guide housing 7 and the lower housing 3. When the guide housing 7 presses the push button 6 downward, the return spring 8 is compressed. When the guide shell 7 is released, the elastic force of the return spring 8 pushes the guide shell 7 upwards, so that the guide shell 7 moves upwards and releases the key 6, thereby resetting. When the outer wall of the guide housing 7 is provided with the buckle 75, the buckle 75 is buckled in the limiting groove 43 of the inner ring 41, the return spring 8 pushes the guide housing 7 upwards and keeps a compression state, the buckle 75 is clamped at the top end of the limiting groove 43, and the guide housing 7 keeps stable at the top end of the stroke so as to be pressed again.

In this embodiment, in order to facilitate connection of the controller with a device or circuit to be controlled, the top of the lower housing 3 is a main control board 31, and the buttons 6 and the hollow encoder 4 are mounted on the main control board 31. The magnetic encoder 5 can also be electrically connected with the main control board 31, and the main control board 31 can transmit the control signals of the button 6, the hollow encoder 4 or the magnetic encoder 5 to the device or circuit to be controlled through a wire or in a wireless communication mode.

When the controller transmits the control signal in a wireless manner, the controller itself needs to solve the power supply problem. For this, the lower case 3 is provided with a battery chamber 32, and a conductive elastic piece 33 mounted on the main control board 31 is positioned in the battery chamber 32. The battery 34 is installed in the battery compartment 32, the cover plate 35 is installed on the filling opening of the battery compartment 32, the battery 34 is pressed and held on the conductive elastic sheet 33 by the cover plate 35, and the battery 34 supplies power for the main control board 31 through the conductive elastic sheet 33. The battery 34 may be an AA battery, a button battery, or other existing battery types, and the conductive elastic sheet 33 may be a structure matched with the corresponding battery type, which is not limited in the invention for selecting the battery type and matching the conductive elastic sheet structure.

In this embodiment, in order to keep the lower housing 3 stable when the controller is used while being placed on a table, a non-slip pad 9 is mounted on the bottom surface of the lower housing 3. The frictional force between slipmat 9 and the desktop is great, can the stable support casing 3 down, keeps its stability to when casing 1 or well casing 2 in the rotating, keep static, corresponding angle displacement can both accurately be surveyed to magnetic encoder 5, cavity encoder 4, thereby accurate control circuit.

In the present embodiment, in order to realize the function of the magnetic encoder 5, the magnetic encoder 5 includes a magnet 51 and a chip board 52 provided with a sensor. The magnet 51 is installed on the upper case 1, and the chip board 52 is installed in the guide case 7; alternatively, the magnet 51 may be mounted in the guide case 7 and the chip board 52 may be mounted on the upper case 1 in a reverse mounting manner. When the upper shell 1 rotates, the magnet 51 and the chip board 52 rotate relatively to generate a changing magnetic field, and the chip board 52 measures the change of the magnetic field to obtain the angular displacement of the rotation of the upper shell 1.

In summary, the invention has the following advantages:

1. according to the push button controller, the inner ring and the outer ring can rotate, so that the control functions of a product are enriched, and the requirements of different electrical appliances on complex control functions can be met;

2. the invention uses the magnetic encoder to replace the traditional mechanical encoder to detect the rotation of the inner ring knob, thus being more beneficial to the reduction of the height of the product and the stability of the product in the rotation process;

3. the invention uses the combination form of the shell and the roller pin to achieve the effect of using the roller pin bearing, the product has lower realization cost and smaller thickness, the stability of rotation can be improved by adjusting the number of the roller pins, and the design is more flexible;

4. according to the invention, the pressing stability of the knob is improved through the matching of the guide shell and the inner hole of the mechanical encoder, the integral up-and-down movement in the knob pressing process is ensured not to be deflected, and the user experience is improved.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A depressible knob controller comprising:

a lower housing;

a hollow encoder mounted on the lower case;

an upper housing rotatably mounted on the guide housing;

2. The depressible knob controller of claim 1, wherein the upper housing is mounted on a top plate of the guide housing, the upper housing comprising:

3. The depressible knob controller of claim 1, wherein the outer wall of the guide housing is provided with a catch, and the inner wall of the inner ring is provided with a limit groove, the catch catching in the limit groove to prevent the guide housing from coming out of the inner ring.

4. The depressible knob controller of claim 1, wherein the guide housing is provided with a projection on an outer wall thereof, and the inner ring is provided with a guide groove axially on an inner wall thereof, the projection being slidably mounted in the guide groove.

5. The depressible knob controller of claim 1, wherein the upper housing and lower housing are both located inside the middle housing.

6. The depressible knob controller of claim 5, wherein an end surface of one end of the middle housing is flush with an upper surface of the upper housing and an end surface of the other end is flush with a bottom surface of the lower housing.

7. The depressible knob controller of claim 1, wherein a return spring is mounted between the guide housing and the lower housing, the guide housing compressing the return spring when sliding down to press the key to generate an upward pushing force to push the guide housing away from the key when returning.

8. The depressible knob controller of claim 7 wherein the top of the lower housing is a main control board on which the buttons and hollow encoder are mounted.

9. The depressible button controller of claim 8, wherein the lower housing is provided with a battery compartment for mounting a battery, and the conductive dome mounted on the main control board is located within the battery compartment;

10. The depressible knob controller of claim 1, wherein a non-slip pad is mounted on a bottom surface of the lower housing.

11. The depressible knob controller of claim 1, wherein the magnetic encoder comprises a magnet mounted on the upper housing and a chip board provided with a sensor mounted in the guide housing.

12. The depressible knob controller of claim 1, wherein the magnetic encoder comprises a magnet and a chip board provided with a sensor, the magnet being mounted within the guide housing, the chip board being mounted on the upper housing.