RU177075U1 - Information input device - Google Patents

Abstract

The invention relates to information input devices, in particular to a capacitive touch keyboard, and can be used in industrial devices operating in difficult conditions. The information input device contains a printed circuit board 1 on which the sensor elements 2 are located for connection with the microcontroller 5, each sensor element 2 is made in the form of two conductive tracks 3, 4, the first conductive path 3 (PDD) is made in the form of a frame with protrusions 7 on one of the sides facing the inside of the frame, the second conductive path 4 (VTD) is located inside the frame and is made in the form of a comb, between the protrusions 8 of which there are protrusions 7 of the PDT 3. The technical result of the utility model is provided the ability to control the keyboard both in the presence of thick reinforced protective screens and without them, thanks to the implementation of the sensor elements intended for communication with the microcontroller of the special form described above.

Description

The invention relates to information input devices, in particular to a capacitive touch keyboard, and can be used in industrial devices operating in difficult conditions.

A capacitive keyboard is known from the prior art, which is the closest solution to the proposed one, containing a board on which the sensor elements are located and a protective element located on the surface of the board with sensor elements (see "Automation and software engineering 2015 No. 1 (11). Design of sensor buttons based on the TTR-224 microcircuit (p. 70-74) ”).

The disadvantages of the known keyboard are: the inability to protect the sensor element (key) with a sufficient thickness protective screen; the complexity of setting up the system (if we talk about the same sensitivity of different keys, then the adjustment will be carried out by selecting electronic components with a minimum range of characteristics); when changing external conditions (humidity, temperature), the parameters of the keys will change from those specified during setup, i.e. the known solution is applicable only in ordinary household products that do not have high requirements for operating conditions; difficulty scaling the number of keys.

The technical problem of the utility model is the elimination of the above disadvantages.

The technical problem of the utility model is solved in that the information input device comprises a printed circuit board on which the sensor elements are located for connection to the microcontroller, and each sensor element is made in the form of two conductive paths: the first conductive path (PDD) is made in the form of a frame with protrusions on one of the sides facing the inside of the frame; the second conductive path (VTD) is located inside the frame and is made in the form of a comb, between the protrusions of which are the protrusions of the PTD.

In addition, the protrusions of the PDD can be parallel to each other and can have the same length.

In addition, the protrusions of the PDD can be located perpendicular to the side of the frame on which they are made and can be located on one side of the frame with the same pitch.

In addition, the protrusions of the VTD can be parallel to each other and can have the same length.

In addition, the protrusions of the IDT can be located perpendicular to the base of the comb and can be located on the base of the comb along the entire length with the same pitch.

In addition, the width of the sides of the frame and its protrusions is mainly greater than the width of the base and protrusions of the comb.

In addition, the PDD can have at least two protrusions, and the TDD can have at least three protrusions.

In addition, a protective element may be installed on the surface of the printed circuit board with sensor elements.

The protective element may be made of a transparent or opaque dielectric material, which may have a thickness of 6 to 40 mm.

In addition, the printed circuit board may have a means of outputting information in the form of a display, or an indicator (a set of indicators).

The technical result of the utility model is the ability to control the keyboard both in the presence of thick reinforced protective screens and without them thanks to the implementation of the sensor elements intended for communication with the microcontroller of the special form described above.

The utility model is illustrated by drawings, where in FIG. 1 shows a proposed information input device; in FIG. 2 shows a communication circuit of sensor elements; in FIG. 3 shows the proposed device as part of an electronic control unit of explosion-proof execution (the case of the block is a flameproof enclosure of class “d”); in FIG. 4 shows a section aa in figure 3; in FIG. 5 shows a pulse transmission circuit.

The information input device (capacitive touch keyboard, hereinafter referred to as the keyboard) is made in the form of a printed circuit board 1 (dielectric base), on the surface of which there are sensor elements 2 (buttons, keys). The number of touch elements 2 (group of touch elements 2) can be any depending on the need and the required functionality of the keyboard. Moreover, the arrangement of elements 2 on the printed circuit board 1 can also be different (depending on the convenience of access to the buttons when executing the keyboard for a specific product).

Each sensor element 2 is made in the form of two conductive tracks 3 and 4 located on the board 1 and connected to the microcontroller 5, which has a special program for controlling the sensor elements 2. Elements 2 can be connected directly to the microcontroller 5, or through a special chip 6. When this communication elements can be any (for example, a connecting cable, a flexible cable, conductive tracks of the printed circuit board, etc., depending on the design features of the final product).

The first conductive track 3 (PTD 3 - transmitter) is made in the form of a rectangular frame. On one side of the frame are connected protrusions 7, facing the inside of the frame and located parallel to each other and perpendicular to the side with which they are connected. The protrusions 7 have the same length and are located on one side of the frame with the same pitch.

The second conductive path (VTD 4 - receiver) is located inside the PDD 3 (inside the frame) and is made in the form of a comb, the base of which is parallel to the side of the frame of the PDD 3, on which the protrusions 7. The protrusions 8 of the comb are located parallel to each other inside the frame, while between the protrusions 8 are the protrusions 7 (the protrusions 7 are parallel to the protrusions 8, and the protrusions 8 are perpendicular to the base of the comb). The protrusions 8 have the same length and are located on the base of the comb along its entire length (from one edge to the other) with the same pitch.

All lines of the PDD 3 (frame with protrusions) of each element 2 are made thickened (wide) compared with the lines of the VTD 4 (compared to the comb).

The number of protrusions 7 on the frame of the PDD 3 can be any depending on the required dimensions of the sensor element 2 and the thickness of the protective screen 9 (the distance at which the touch is recognized), while the minimum number of protrusions 7 is two. The number of protrusions 8 of the comb VTD 4 can also be any, while the minimum number of protrusions 8 is three. The number of protrusions 8 VTD 4 is always greater than the number of protrusions 7 PDD 3 per protrusion 8.

On the surface of the printed circuit board 1 with sensor elements 2, a protective element 9 (protective screen) is installed, made in the form of a transparent or opaque dielectric material. If the element 9 is made opaque, the buttons are marked on its working surface in the area where the elements 2 are located (opposite them). The protective element 9 may have a thickness of 6 to 40 mm, which allows the keyboard to work in the event of mechanical stress on it, in the event of shock or explosion, as well as in other difficult conditions.

The printed circuit board 1 may have a means of outputting information 10, made in the form of a display, or indicator (a set of indicators), reflecting information about the keystrokes.

The device works in direct connection with the microcontroller 5, which has a special program for controlling the sensor elements 2. Using the digital interface of the microcontroller 5, parameters for determining the pressure on the elements 2 are set (for example, they adjust the sensitivity for a specific material and the thickness of the protective screen 9). In the same interface, the state of the keys is transmitted (information about the keystroke, extended data on the status, calibration, insufficient signal received by the channel, etc.). The microcontroller 5 through the microcircuit 6 (directly or without; the microcircuit 6 generates pulses and measures the levels of the buttons 2) sends pulses (signals) to the wide PDT 3, and through them to the narrow VTD 4. At the VTD 4 the received signal level is constantly measured. When the button 2 is exposed to the area of the conductive object, the level changes, these changes are processed by the microcontroller 5.

Due to the implementation of the proposed capacitive keyboard in the manner described above, i.e. a special form of elements 2, the physical principle and the correct processing of the received signal (a signal sent by the transmitting part of the system with certain characteristics, reflected, scattered, absorbed by the environment, is received by the receiving part of the system, then it is processed, compared with the characteristics set when the system was set up, after several iterations made with different values of the signal sent, a decision is made to touch / not touch the key), it is possible to control I keyboard through thick reinforced protective screens 9. The proposed keyboard with sensor elements 2 is installed in various systems of human-computer interaction in industrial devices operating in difficult conditions. The keyboard is located inside the protective shell (housing) of the product behind the area of dielectric material, which may be part of a protective shell (housing) of arbitrary shape.

Structurally, a capacitive keyboard consists of a group of sensor elements 2 representing conductive tracks 3, 4 of a special shape deposited on a dielectric base 1 and connected to a specialized electronic circuit 6 based on a microcontroller 5, with the function of measuring the change in capacitance by monitoring charge transfer from one electrode of the sensor element another. Simplicity of design and the absence of special requirements for production increase manufacturability and reduce the cost of the final product. The absence of moving parts in the proposed technical solution increases the reliability and durability of the final product.

The technology used in the utility model for determining the change in capacitance on the effect of charge transfer in conjunction with the special form of the sensor elements and with the microcontroller 5 allows you to determine the touch through any reinforced (thick) dielectric material (for example, various types of plastics and glasses) up to 40 mm thick, which can be part of the body of the product, or made directly in conjunction with the keyboard. This thickness of the protective element 9 allows you to use the proposed solution in the composition of products that impose increased requirements for the strength (shell) of the housing (for example, inside an explosion-proof enclosure of class “d”).

The absence of external parts allows the use of this utility model in products that have increased requirements for dust and moisture protection, up to IP68.

A wide range of materials through which touch recognition is possible, allows you to use the proposed keyboard as part of devices with increased requirements for protection from aggressive environments.

Symbols that indicate places of contact can be applied both from the inside (shell) of the case, subject to the transparency (shell) of the case, and from the outside.

In addition, the proposed device allows you to enter information in personal protective equipment (for example, rubber or cotton gloves).

A special form of sensitive elements used in the proposed utility model allows to increase the density of the location of touch points, which positively affects the overall dimensions of the final product.

The possibility of manufacturing the sensitive element 2 from a flexible material allows you to create products with a complex surface.

Claims (16)

1. An information input device comprising a printed circuit board on which sensor elements are arranged for connection with a microcontroller, characterized in that each sensor element is made in the form of two conductive tracks, the first conductive path (PDD) is made in the form of a frame with protrusions on one side facing the inside of the frame, the second conductive path (VTD) is located inside the frame and is made in the form of a comb, between the protrusions of which are the protrusions of the PTD. 2. The device according to p. 1, characterized in that the protrusions of the PDD are parallel to each other. 3. The device according to p. 1, characterized in that the protrusions of the PDD have the same length. 4. The device according to p. 1, characterized in that the protrusions of the PDD are perpendicular to the side of the frame on which they are made. 5. The device according to claim 1, characterized in that the protrusions of the PDD are located on one side of the frame with the same pitch. 6. The device according to p. 1, characterized in that the protrusions of the VTD are parallel to each other. 7. The device according to p. 1, characterized in that the protrusions of the VTD have the same length. 8. The device according to p. 1, characterized in that the protrusions of the VTD are perpendicular to the base of the comb. 9. The device according to p. 1, characterized in that the protrusions of the VTD are located on the base of the comb along the entire length with the same pitch. 10. The device according to p. 1, characterized in that the width of the sides of the frame and its protrusions is greater than the width of the base and protrusions of the comb. 11. The device according to p. 1, characterized in that the PDD has at least two protrusions, and the VTD has at least three protrusions. 12. The device according to claim 1, characterized in that a protective element is installed on the surface of the printed circuit board with sensor elements. 13. The device according to p. 12, characterized in that the protective element is made of a transparent dielectric material. 14. The device according to p. 12, characterized in that the protective element is made of an opaque dielectric material. 15. The device according to p. 12, characterized in that the protective element has a thickness of from 6 to 40 mm 16. The device according to p. 1, characterized in that the printed circuit board has a means of outputting information.

Images