KR102631429B1 - Button device that can use both contact and non-contact methods simultaneously and recognition method thereof - Google Patents

Abstract

The present invention relates to a button device that can be used simultaneously with contact and non-contact and a recognition method thereof. In particular, both contact and non-contact input methods can be used using a proximity sensor and a contact switch, and the existing contact button device can be used. This relates to a button device that can be used interchangeably at the same time as contact and non-contact, and a recognition method thereof. The present invention is equipped with both a proximity sensor and a contact switch to provide both a non-contact input method and a contact input method at the same time, so it can be applied without conflict with laws related to the visually impaired. Additionally, the present invention can minimize user confusion or resistance because the exterior is the same as the existing button. The present invention can be applied to existing elevators at minimal cost because it only requires replacing the button device or adding minimal devices such as a control board. The present invention can be used by visually impaired people in the same way as before, so there is no additional inconvenience and there is no need to learn new methods of use.

Description

Button device that can use both contact and non-contact methods simultaneously and recognition method thereof}

The present invention relates to a button device that can be used simultaneously with both contact and non-contact and a recognition method thereof. In particular, both contact and non-contact can be used using a proximity sensor and a contact switch, and it can be used by replacing the existing contact button device. This relates to a button device that can be used simultaneously in both contact and non-contact mode and its recognition method.

Due to the global COVID-19 Pandemic, interest in non-contact/non-face-to-face technology that can prevent infection from unspecified others is increasing more than ever. For example, elevators are a representative unspecified multi-use facility that is encountered on a daily and repeated basis, and due to concerns about infection through the buttons, it has recently become common to cover the buttons with antibacterial and antiviral films. However, the antibacterial and antiviral effects of this film have not been verified, and even if it has an antiviral effect, it is known that no practical effect can be expected unless it is replaced every day. Therefore, replacing all buttons in multi-use facilities, including elevators, with non-contact methods can be said to be the most effective means of preventing infection through multi-use facilities.

Here, in order to fully introduce non-contact buttons, several legal, customary, and functional issues must be resolved. First, it must meet the 'Act on Guaranteeing the Promotion of Convenience for the Disabled, the Elderly, and Pregnant Women', which requires attaching Braille for the visually impaired to the surfaces of buttons in multi-use facilities such as elevators. Second, it must be compatible with existing multi-use facility buttons. If the existing button panel must be completely replaced or additional devices must be attached to introduce non-contact buttons, the demand for introducing non-contact buttons into existing multi-use facilities will be greatly limited. Third, there should be no difference from the usage of existing multi-use facilities. If the method of using the non-contact button is significantly different from the method of using the existing contact button, users are bound to be confused, which can make it virtually impossible to attempt to use the contact/non-contact method in common.

However, to date, only technologies that operate only in contact or non-contact types have been developed, and a button device that can be used for both contact and non-contact types is required.

Republic of Korea Registered Utility Model No. 20-0442312 (registered on October 21, 2008) Republic of Korea Patent No. 10-1066290 (registered on September 14, 2011) Republic of Korea Patent No. 10-1169457 (registered on July 23, 2012)

The purpose of the present invention is to provide a button device that can be used both contact and non-contact simultaneously by replacing the existing contact button device, and a recognition method thereof.

Another object of the present invention is to provide a button device that can be used simultaneously with both contact and non-contact, including a non-contact button device or a contact type for the visually impaired, and a recognition method thereof.

A button device that can be used simultaneously in contact and non-contact according to the present invention includes at least one button module including a button, a proximity sensor for detecting an object, and a contact switch operated by pressing the button, the button module, and It includes a control board that is electrically connected, wherein when input is received from two or more different button modules within a predetermined time, a non-contact signal generated when the proximity sensor detects an object and the contact switch operates. Among the contact signals generated, non-contact signals from two or more different button modules that received input within the predetermined time are ignored.

When receiving inputs from two or more different button modules within a predetermined time, the control board selects the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated for the predetermined time. Both non-contact signals and contact signals from two or more different button modules that are input within the same period may be ignored.

In addition, the button device that can be used simultaneously in contact and non-contact according to the present invention includes at least one button module including a button, a proximity sensor for detecting an object, and a contact switch operated by pressing the button, and the button. It includes a control board electrically connected to the module, wherein the control board is configured to generate a non-contact signal generated when the proximity sensor detects an object when both the proximity sensor and the contact switch are activated within a predetermined time and the contact switch is connected to the non-contact signal. Among the contact signals generated when the switch is activated, control can be performed according to the contact signal.

However, in the button device that can be used simultaneously with contact and non-contact according to the present invention, the control board generates a non-contact button when both the proximity sensor and the contact switch are activated within a certain time, and the proximity sensor detects an object. Control may be performed according to the non-contact signal among the contact signals generated when the contact switch is activated.

The control board is provided separately from the button module, and the contact signal and the non-contact signal can be generated in the control board.

However, the present invention is not limited to this, and the button module includes a control panel that generates a non-contact signal when the proximity sensor detects an object and generates a contact signal when the touch switch operates, and the control board may receive at least one of the non-contact signal and the contact signal from the control panel.

The proximity sensor uses a sensor that detects the approach of an object by generating electromagnetism, a sensor that recognizes the proximity of an object using ultrasonic waves, a sensor that recognizes the coordinates of a button using light, and a ToF (Time of Flight) sensor. Thus, it may include a sensor that measures the distance to the object by measuring the time the light is reflected and received by the object.

In addition, the recognition method of a button device that can be used simultaneously with contact and non-contact according to the present invention is a button recognition method using a button device that can be used simultaneously with contact and non-contact according to the above-described structure, comprising the steps of the button module receiving an input, and a predetermined time Receiving input from a button module different from the button module within a certain time, when the control board receives input from two or more different button modules within a predetermined time, a non-contact signal generated when the proximity sensor detects an object and the contact Among the contact signals generated when the type switch is activated, a step is performed to ignore non-contact signals from two or more different button modules that have received input within the predetermined time.

In this case, when the control board receives input from two or more different button modules within a set time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, A step of ignoring contact signals from two or more different button modules that have received input within the predetermined time may also be performed.

In addition, the recognition method of a button device that can be used simultaneously with contact and non-contact according to the present invention is a button recognition method using a button device that can be used simultaneously with contact and non-contact according to the above-described structure, comprising the steps of the proximity sensor of the button module receiving an input; , a step in which the contact switch of the button module receives an input within a predetermined time, the control board generates an input when both the proximity sensor and the contact switch of the same button module receive input within a predetermined time, and the proximity sensor detects an object. It includes performing control according to the contact signal among a non-contact signal that is generated and a contact signal that is generated when the touch switch is activated.

In addition, the recognition method of a button device that can be used simultaneously with contact and non-contact according to the present invention is a button recognition method using a button device that can be used simultaneously with contact and non-contact according to the above-described structure, comprising the steps of the proximity sensor of the button module receiving an input; , a step in which the contact switch of the button module receives an input within a predetermined time, the control board generates an input when both the proximity sensor and the contact switch of the same button module receive input within a predetermined time, and the proximity sensor detects an object. It may include performing control according to the non-contact signal among the non-contact signal that is generated and the contact signal that is generated when the touch switch is activated.

The button device and its recognition method that can be used simultaneously with contact and non-contact according to the present invention are equipped with both a proximity sensor and a contact switch, providing both a non-contact input method and a contact input method at the same time, so that they can be applied without conflict with laws related to the visually impaired.

In addition, the button device and its recognition method that can be used simultaneously with contact and non-contact according to the present invention can minimize user confusion or resistance because the external appearance is the same as that of existing buttons.

The button device and its recognition method that can be used simultaneously with both contact and non-contact according to the present invention can be applied to places such as existing elevators at minimal cost because only the button device needs to be replaced or only a minimal device such as a control board is added.

The button device and its recognition method that can be used simultaneously with contact and non-contact according to the present invention can be used by visually impaired people in the same way as before, so there is no additional inconvenience and there is no need to learn new methods of use.

In addition to the above-described effects, specific effects of the present invention are described below while explaining specific details for carrying out the invention.

Figure 1 is a plan view of a non-contact button device excluding buttons from the button device that can be used simultaneously with contact and non-contact according to the present invention.
Figure 2 is a cross-sectional view of a button device that can be used simultaneously in contact and non-contact according to the present invention.
Figure 3 is a plan view of a button device that can be used simultaneously in contact and non-contact according to the present invention.
Figure 4 shows a light emitting unit control signal applied from the light emitting unit control module of the non-contact button device according to the present invention.
Figure 5 is a diagram for explaining an input blocking module in a button device that can be used simultaneously in contact and non-contact according to the present invention.
Figures 6 and 7 are conceptual diagrams showing recognition areas according to the light emission angle of the light emitting unit.
Figure 8 is a conceptual diagram illustrating the angles of the light emitting unit and the light receiving unit in the button device that can be used simultaneously in contact and non-contact according to the present invention.
Figure 9 is a conceptual diagram for explaining a guide in a button device that can be used simultaneously in contact and non-contact according to the present invention.
Figure 10 is a photograph of a button device provided in an elevator.
Figure 11 is a photograph of the button device and main board provided in the elevator.

The above-mentioned objects, features, and advantages will be described in detail later with reference to the attached drawings, so that those skilled in the art will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of known technologies related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings. In the drawings, identical reference numerals are used to indicate identical or similar components.

Figure 1 is a plan view of a non-contact button device excluding buttons in a button device that can be used simultaneously with contact and non-contact according to the present invention, and Figure 2 is a cross-sectional view of a button device that can be used simultaneously with contact and non-contact according to the present invention. In addition, Figure 3 is a plan view of a button device that can be used simultaneously in contact and non-contact according to the present invention.

As shown in FIGS. 1 to 3, the button device that can be used simultaneously in contact and non-contact according to the present invention includes a button 100 equipped with a light-transmitting cover 110 in some open areas, and a light transmitting cover 110. A proximity sensor 200 that receives reflected light after irradiation, a contact switch 300 that operates by pressing the button 100, and the light received from the proximity sensor 200 or the contact switch 300. A housing ( 500), and a connector 600 that is exposed to one side of the housing 500 and transmits the signal generated in the control panel 400 to the outside. Here, the button 100, the proximity sensor 200, the contact switch 300, the control panel 400, the housing 500, and the connector 600 can be defined as a button module, and the present invention provides such a button module. Multiple units can be gathered together and connected to the control board.

The button 100 receives input from the user and operates the touch switch 300. This embodiment illustrates that a non-contact button device is applied to an elevator, and as shown in FIG. 3, numbers and Braille indicating the number of floors are formed on the outer surface of the button 100. That is, the button 100 of this embodiment refers to a cover that covers the open housing 500 and can be reciprocated by the spring of the contact switch 300 or another return structure. Additionally, the button 100 includes a polygonal, circular, or oval plate shape including triangles and squares, and this embodiment illustrates the button 100 in a circular plate shape for convenience of explanation. The button 100 is formed with an opening in which some areas are open, which is exemplified as being open in a circular shape as shown. Of course, the present invention is not limited to this, and the opening may be formed in a polygonal shape, including a triangle, or an oval shape. Here, the opening of the button 100 is provided with a light-transmitting cover 110 made of crystal or resin to which a black filter is applied to close the inside of the button 100 from the outside, but the light emitted from the internal proximity sensor 200 is This transmitted and reflected light may be transmitted and received by the proximity sensor 200.

The proximity sensor 200 detects the approach of an object, such as a user's finger, at a predetermined distance. These proximity sensors 200 include a sensor that detects the approach of an object by generating electromagnetism, a sensor that recognizes the proximity of an object using ultrasonic waves, a sensor that recognizes the coordinates of a button using light, and a ToF (Time of Flight) sensor. It may include a sensor that measures the distance to the object by measuring the time the light is reflected and received by the object. However, regardless of the type of proximity sensor 200, the present invention provides various non-contact methods that recognize when an object, including a human body or belongings held by the human body, is located in an arbitrary virtual space above a tangible button. The button can be used as a proximity sensor 200.

Meanwhile, this embodiment illustrates an optical sensor as the proximity sensor 200, and the optical sensor emits light and then receives reflected light reflected by an object, for example, a finger or palm. As shown in FIGS. 1 and 2, this optical sensor includes a light emitting unit 210 that emits light and a light receiving unit 220 that receives reflected light.

The light emitting unit 210 is located inside the button 100 and emits light through the light-transmitting cover 110. Additionally, the light emitted from the light emitting unit 210 through the light transmitting cover 110 is reflected by the user's hand and enters the light receiving unit 220, which will be described later. Of course, the light emitted through the light-transmitting cover 110 may be reflected not only by the user's hand but also by a bag or arm, but in this embodiment, only the reflected light reflected by the user's hand is judged to be normal. Additionally, for this purpose, in this embodiment, the control unit, which will be described later, determines whether the reflected light received by the light receiving unit 220 is normal. Meanwhile, the present invention can use an ultrasonic sensor or an infrared light-emitting diode as the light emitting unit 210. However, ultrasonic sensors respond more sensitively to temperature and atmospheric pressure than infrared light-emitting diodes. Therefore, when applied to elevators in high-rise buildings that rapidly go up and down between high and low floors, there is a risk of malfunction, so it is preferable to use an infrared light-emitting diode (IR LED), which is the proximity sensor 200, rather than an ultrasonic sensor. Therefore, this embodiment illustrates an infrared light-emitting diode as the light-emitting unit 210, and the light-emitting unit 210 is preferably mounted on the control panel 400, that is, a substrate, and emits light to the light-transmitting cover.

The light receiving unit 220 receives reflected light emitted from the light emitting unit 210 and reflected. This embodiment illustrates a photo diode as the light receiving unit 220, and the light receiving unit 220 transmits a light receiving signal for the received reflected light, that is, a non-contact signal, to the control panel 400, which will be described later. Here, the light receiving unit 220 may also receive reflected light through the light transmitting cover 110.

The touch switch 300 is pressed by a user's push input applied to the button 100 to generate a touch signal. This is performed by turning the touch switch 300 on by a push input, and the generated touch signal is transmitted to the control panel 400, which will be described later. Of course, the contact switch 300 is equipped with a spring inside, so it is turned on and turned off again after the switch contact point touches it, restoring the position of the button 100.

The control panel 400 controls the light emitting unit 210 and generates a unique signal based on a non-contact signal received from the light receiving unit 220 or a contact signal received from the touch switch 300. Additionally, for this purpose, the control panel 400 may be in the form of a board, and may be equipped with a chip or circuit on the board that can control the light emitting unit 210 and determine input. Of course, in the case of a chip, an example may be an MCU with a built-in program that performs the corresponding function. Here, in the present invention, the control board connected to the control panel 400 or the main board of the elevator can perform unique control according to a contact signal or a non-contact signal. However, for convenience of explanation, this embodiment is described as the control panel 400 performing the role of the control board or main board, and the control panel 400 includes a light emitting unit control module that controls the light emitting unit 210 and an input It includes an input judgment module that makes judgments.

Figure 4 shows a light emitting unit control signal applied from the light emitting unit control module of the non-contact button device according to the present invention.

The light emitting unit control module controls the light emitting unit 210 so that the light emitting unit 210 emits light through the light transmitting cover 110. Here, for efficient signal analysis, the light emitter control module generates and applies a light emitter control signal divided into pulses of 1 ms to 5 ms as shown in FIG. 4. In addition, according to this, the light emitting unit 210 emits light while blinking at intervals of 1 ms to 5 ms by the light emitting unit control signal. This is because programming is much easier to measure the number of pulses reflected and received by a target object than to measure the time the light is reflected and received by a continuous light emitting unit control signal. However, the present invention is not limited to this, and the pulse unit of the light emitting unit control signal may exceed 5ms.

The input determination module determines the input based on the non-contact signal received from the light receiving unit 220 or the contact signal received from the touch switch 300. To this end, the input judgment module includes an input blocking module, an input delay module, a non-contact signal recognition module that recognizes a non-contact signal, and a contact signal recognition module that recognizes a contact signal.

Figure 5 is a diagram for explaining an input blocking module in a button device that can be used simultaneously in contact and non-contact according to the present invention.

The input blocking module blocks an input non-contact signal or an input contact signal to prevent malfunction, that is, incorrect input. The conventional contact button device has a simple structure in which the user presses an odd number of times to select, and when the user presses an even number of times to cancel the selection, there is no need for a complex algorithm for button selection and cancellation. On the other hand, a button device that uses both non-contact and contact has the same physical structure. Because non-contact input devices and contact input devices coexist in space, various problems that did not occur in the past arise. For example, in the case of a user who does not know or ignores the existence of the non-contact button and uses the contact button, he or she must inevitably pass through the non-contact recognition area in order to press the contact button. Therefore, the user's act of selecting a contact button inevitably causes non-contact selection and contact selection at the same time, and the problem of how to handle this is a problem that must be newly defined by the present invention. To solve this problem, the present invention prevents erroneous input through an input blocking module.

For example, as shown in Figure 5, when input is received from two or more different button modules within a certain time, the non-contact signals of the two or more different button modules that received the input within a certain time can be blocked and ignored. there is. In this case, since only the contact signal is recognized as a normal signal, it is possible to prevent incorrect input by placing an object such as an arm or bag on several button modules close to the user in order to operate a specific button module. Additionally, when the input blocking module receives input from two or more different button modules within a predetermined time, it may ignore both non-contact signals and contact signals from the two or more different button modules that received input within the predetermined time. In this case, in addition to the malfunction of the non-contact signal described above, it is possible to prevent erroneous inputs in which multiple button modules are operated when a visually impaired person touches the multiple button modules with the palm of his or her hand to press a button or cleans the multiple button modules with a rag.

Additionally, the input blocking module can block the non-contact signal to perform control according to the contact signal when both the proximity sensor and the contact switch of the same button module are activated within a predetermined time. However, the present invention is not limited to this, and the input blocking module can block the contact signal to perform control according to the non-contact signal when both the proximity sensor and the touch switch of the same button module are activated within a predetermined time. in this case,

If you press a contact button on the same button module, it will inevitably pass through the recognition area of the proximity sensor 200. Therefore, in order to prevent incorrect input due to this, there is a time difference in receiving the non-contact signal, and if the contact signal and the non-contact signal are received continuously within a certain time, the non-contact signal is ignored, and the time interval between the non-contact signal and the contact signal is defined. Therefore, if a non-contact signal and a contact signal are input simultaneously within a set time interval, a method of ignoring the contact signal can be used. Of course, there is no difference from the user's perspective regardless of whether the non-contact signal or the contact signal is ignored.

Meanwhile, input by non-contact input is canceled by re-entering the non-contact input, or input by contact input is canceled by re-entering the contact input.

The non-contact signal recognition module recognizes a non-contact signal by the proximity sensor 200 and receives input. Additionally, when the non-contact signal recognition module recognizes a non-contact signal, it outputs its own unique signal through the connector 600. For example, in the case of an elevator, this may be a unique signal for the 7th floor out of multiple floors.

The touch signal recognition module recognizes the touch signal from the touch switch 300 and receives input. When the touch signal recognition module also recognizes the touch signal, it outputs its own unique signal through the connector 600.

Here, the function of the input judgment module described above may be performed on a control board, that is, a main board or control board, rather than the control panel 400 provided in each button module. In this case, the control panel 400 simply generates a unique signal, and the generated unique signal is transmitted to the control board, and the control board performs a specific control according to the unique signal, for example, in the case of an elevator, the floor corresponding to the unique signal. You can move to .

Meanwhile, in the present invention, the proximity sensor 200 receives input only from a recognition area spaced a predetermined distance away from the button. In this embodiment, the predetermined distance is 5 mm to 15 mm, and accordingly, input can be performed only within a distance of 5 mm to 15 mm from the button 100. In this way, assuming that it is most convenient to use to recognize the user's finger at a distance of about 5 mm to 15 mm from the surface of the button 100, at that distance the user places his or her finger within an imaginary circle with a diameter of 10 mm to 15 mm. In order to be recognized when positioned, the area where the light emission angle of the light emitting unit 210 and the reflected light receiving range of the light receiving unit 220 intersect becomes the user's finger recognition area. Here, in order to set the input recognition area to 10mm to 15mm, the output of the optical or ultrasonic signal can be adjusted so that the signal reaches only the corresponding distance. However, it is impossible with current technology to adjust the reach of the optical signal in units of mm or cm. Therefore, it is conceivable to measure the distance by measuring the time it takes for light to reflect and return to a specific object using a ToF (Time of Flight) sensor. However, considering the price of the ToF sensor and the complexity of application, not only is it not economically feasible to install ToF sensors one by one on many buttons, but it is also technically not possible because the minimum measurable distance of the ToF sensor must be approximately 20 mm or more. You can consider measuring the distance to a specific object using triangulation as the following method. To utilize triangulation, at least two reference points are needed, so at least two pairs of sensors are needed within the same button. However, considering that the size of buttons such as elevators is only about 40mm in diameter, it is difficult to apply this method. Therefore, a method of measuring distance using an ultrasonic sensor may be considered. Sound waves move at a speed of 340 meters per second, or 1/340,000 of a second per millimeter, so by measuring the arrival time of sound waves reflected from a specific object, the distance to that object can be measured. However, this method also requires a pair of ultrasonic sensors consisting of a transmitting and receiving function to be mounted within the button, and considering the relatively high price of the ultrasonic sensor, it is realistically difficult to apply it to a non-contact button. In addition, since it is impossible to control the emission angle of sound waves, it is difficult to solve the problem of interference with adjacent button modules. Therefore, the present invention adjusts the angle of the light emitting unit 210 and the light receiving unit 220 or adjusts the light emission angle of the light emitting unit 210 using a concave lens or a convex lens to emit light at a specific angle.

Figures 6 and 7 are conceptual diagrams showing recognition areas according to the light emission angle of the light emitting unit. In addition, Figure 8 is a conceptual diagram for explaining the angles of the light emitting unit and the light receiving unit in the button device that can be used simultaneously in contact and non-contact according to the present invention.

Referring to Figures 6 and 7, it may differ depending on the light emitting unit 210, but when installed perpendicular to the surface of the button without adjusting the angle of the light emitting unit 210, the light emission angle of the light emitting unit 210 is When the angle is 30 degrees, a recognition area is formed in the form of a circle with a diameter of 6 mm at 10 mm from the outer surface of the button 100. When the light emission angle is 60 degrees, a recognition area is formed in the shape of a circle with a diameter of 14 mm at 10 mm from the outer surface of the button 100. This can be formed. Therefore, as shown in FIG. 8, the present invention adjusts the light emission angle of the light emitting unit 210 and the light receiving angle of the light receiving unit 220 to create a diameter of about 15 mm to 20 mm in a space of 5 mm to 15 mm on the button 100. The branches form a virtual cognitive space.

Figure 9 is a conceptual diagram for explaining a guide in a button device that can be used simultaneously in contact and non-contact according to the present invention.

The present invention may be provided with a guide 211 so that light is emitted only in a specific width. As shown in FIG. 9, a truncated cone-shaped guide 211 that can make the range (angle) of the light emitting unit 210 narrow or wide is mounted on the front of the light emitting unit 210, so that the optical signal is emitted only in a specific range. When this is intersected with the light receiving range of the light receiving unit 220, reflected light can be received by the light receiving diode only when a specific object exists in the crossed area.

The following describes the installation of a button device that can be used simultaneously with contact and non-contact according to the present invention.

Figure 10 is a photograph of a button device provided in an elevator, and Figure 11 is a photograph of a button device and a main board provided in an elevator.

The present invention is provided with a plurality of button devices that can be used simultaneously in contact and non-contact, and can be installed in a modular manner like the elevator button in FIG. 10. Here, referring to FIG. 11, the button device that can be used simultaneously with contact and non-contact according to the present invention is a button device according to the present invention that can be used by disconnecting the existing button device and attaching it to the existing connector when there is no separate control board in the existing elevator. Connect and install the connector of the button device that can be used simultaneously as contact and non-contact. However, in this case, the firmware of the existing main board must be updated to control the non-contact button device according to the present invention.

However, when a separate control board is provided, the button device that can be used simultaneously in contact and non-contact according to the present invention is connected to the control board and a connector, and the control board is again connected to the main board of the elevator. In this case, the control board converts the unique signal input from the button device that can be used simultaneously with contact and non-contact according to the present invention into the same signal as the signal sent to the main board by the button device previously installed in the elevator and transmits it to the main board. In this case, updating the main board firmware of the existing elevator is not necessary.

As such, the present invention can use both contact and non-contact methods by replacing only various button devices including those in existing elevators.

Next, a method for recognizing a button device that can be used simultaneously in both contact and non-contact mode according to the present invention will be described.

The method of recognizing a button device that can be used simultaneously with contact and non-contact according to the present invention includes the steps of receiving an input by a button module and performing control according to the button module that received the input.

The step of receiving input by a button module includes a step of receiving input by one and the same button module, and a step of receiving input by different button modules.

The step of performing control according to the button module that receives the input is the step of the button module receiving the input, and control is performed depending on which button module received the input from which proximity sensor or contact switch. Here, the step of performing control according to the button module that receives the input includes receiving input from a button module and a different button module within a predetermined time, and the control board receiving input from two or more different button modules within a predetermined time. In this case, a step is performed to ignore non-contact signals from two or more different button modules that have received input within a set time. Here, in addition to ignoring non-contact signals from two or more different button modules that have received input within a predetermined time, contact signals can also be ignored. In this case, all inputs to more than one button module will be ignored.

However, the present invention is not limited to this, and the step of performing control according to the button module that receives the input is that when the same button module receives input from both the proximity sensor and the touch switch within a certain time, the control board responds to the touch signal. It may also include a step of performing control accordingly. Of course, this is not limited, and on the contrary, if the same button module receives input from both the proximity sensor and the contact switch within a certain time, the control board may perform the step of performing control according to the non-contact signal. Here, when a non-contact signal is received from two or more adjacent buttons within a set time, the non-contact mode of the entire button panel can be canceled and converted to a contact mode, or it can be programmed to ignore only the signal from the corresponding button regardless of proximity. there is. In the former case, since the type and number of adjacent buttons vary depending on the number of floors of the building and the arrangement of the button panel, a problem arises in which button modules adjacent to each elevator must be separately defined, whereas in the latter case, such a problem does not occur. On the other hand, in the latter case, a problem occurs in which the non-contact mode does not work even when multiple users simultaneously make non-contact selections that are not adjacent to each other. In addition, while the former matches the user's actual intention, implementing it as an actual program is likely to cause user inconvenience due to the risk of malfunction and delay in recognition time. In the latter, the user thinks he has pressed the contact button, but in reality, a non-contact signal has been selected, and an attentive user is likely to notice this. However, this has the advantage of significantly reducing problems such as the risk of malfunction or delay in recognition time, while there is little possibility of user complaints or protests. Therefore, it is more efficient to selectively use the former and the latter depending on the number of floors and usage environment of the elevator.

As described above, the present invention relates to a button device that can be used simultaneously with both contact and non-contact and a recognition method thereof. In particular, both contact and non-contact input methods can be used by using a proximity sensor and a contact switch, and it can be used to It relates to a button device that can be used simultaneously as a contact and non-contact button device that can be used by replacing a contact button device and a recognition method thereof. The present invention is equipped with both a proximity sensor and a contact switch to provide both a non-contact input method and a contact input method at the same time, so it can be applied without conflict with laws related to the visually impaired. Additionally, the present invention can minimize user confusion or resistance because the exterior is the same as the existing button. The present invention can be applied to existing elevators at minimal cost because it only requires replacing the button device or adding minimal devices such as a control board. The present invention can be used by visually impaired people in the same way as before, so there is no additional inconvenience and there is no need to learn new methods of use.

As described above, the present invention has been described with reference to the illustrative drawings, but the present invention is not limited to the embodiments and drawings disclosed herein, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. It is obvious that transformation can occur. In addition, although the operational effects according to the configuration of the present invention were not explicitly described and explained while explaining the embodiments of the present invention above, it is natural that the predictable effects due to the configuration should also be recognized. For example, the present invention can be applied to devices that use touch buttons, such as building entrance locks and door locks, in addition to elevators.

100: button 110: flood cover
200: Proximity sensor 210: Light emitting unit
211: guide 220: light receiving unit
300: touch switch 400: control panel
500: Housing 600: Connector

Claims (11)

At least one button module including a button, a proximity sensor for detecting an object, and a touch switch operated by pressing the button,
Includes a control board electrically connected to the button module,
The proximity sensor includes a light emitting unit that emits light, and a light receiving unit that receives reflected light reflected from the light emitted from the light emitting unit,
The light emitting unit and the light receiving unit are tilted to face each other, and an area where reflected light receiving ranges intersect becomes a recognition area,
The control board includes a light emitting unit control module that generates and applies a light emitting unit control signal divided into pulses of a predetermined unit to the light emitting unit and measures the number of pulses received by the light receiving unit,
When receiving inputs from two or more different button modules within a predetermined time, the control board selects the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated for the predetermined time. A button device that can be used simultaneously with contact and non-contact that ignores non-contact signals from two or more different button modules that are input within the same time, but cancels the contact signal with a contact signal and cancels the non-contact signal with a non-contact signal.
According to paragraph 1,
The control board is,
When input is received from two or more different button modules within a set time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, the one that receives the input within the set time A button device that can be used simultaneously as both contact and non-contact, ignoring both non-contact and contact signals from two or more different button modules.
At least one button module including a button, a proximity sensor for detecting an object, and a touch switch operated by pressing the button,
Includes a control board electrically connected to the button module,
The proximity sensor includes a light emitting unit that emits light, and a light receiving unit that receives reflected light reflected from the light emitted from the light emitting unit,
The light emitting unit and the light receiving unit are tilted to face each other, and an area where reflected light receiving ranges intersect becomes a recognition area,
The control board includes a light emitting unit control module that generates and applies a light emitting unit control signal divided into pulses of a predetermined unit to the light emitting unit and measures the number of pulses received by the light receiving unit,
The control board is configured to select between a non-contact signal generated when the proximity sensor detects an object and a contact signal generated when the contact switch is activated when both the proximity sensor and the contact switch of the same button module are activated within a predetermined time. A button device that performs control according to a contact signal, but cancels the contact signal with a contact signal and cancels the non-contact signal with a non-contact signal, allowing simultaneous use of contact and non-contact.
At least one button module including a button, a proximity sensor for detecting an object, and a touch switch operated by pressing the button,
Includes a control board electrically connected to the button module,
The proximity sensor includes a light emitting unit that emits light, and a light receiving unit that receives reflected light reflected from the light emitted from the light emitting unit,
The light emitting unit and the light receiving unit are tilted to face each other, and an area where reflected light receiving ranges intersect becomes a recognition area,
The control board includes a light emitting unit control module that generates and applies a light emitting unit control signal divided into pulses of a predetermined unit to the light emitting unit and measures the number of pulses received by the light receiving unit,
The control board is configured to select between a non-contact signal generated when the proximity sensor detects an object and a contact signal generated when the contact switch is activated when both the proximity sensor and the contact switch of the same button module are activated within a predetermined time. A button device that performs control according to a non-contact signal, but cancels the contact signal with a contact signal and cancels the non-contact signal with a non-contact signal. A button device that can be used simultaneously with contact and non-contact.
According to any one of claims 1 to 4,
The control board and the button module are installed in an elevator equipped with a main board,
The control board is provided separately from the button module and connected to the main board,
The contact signal and the non-contact signal are generated by the control board, converted into a signal that can be recognized by the main board, and transmitted to the main board. A button device that can be used simultaneously with contact and non-contact.
According to any one of claims 1 to 4,
The button module includes a control panel that generates a non-contact signal when the proximity sensor detects an object and generates a contact signal when the touch switch operates,
A button device capable of simultaneous use of contact and non-contact, wherein the control board receives at least one of the non-contact signal and the contact signal from the control panel.
According to any one of claims 1 to 4,
A button device that can be used simultaneously in contact and non-contact, further comprising a truncated cone-shaped guide that limits the light emission range of the light emitting unit.
A button recognition method using a button device capable of simultaneous contact and non-contact use according to any one of claims 1 to 4, comprising:
A step where the button module receives input,
Receiving input from a button module different from the button module within a set time,
When the control board receives input from two or more different button modules within a predetermined time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, the predetermined time A recognition method for a button device that can be used simultaneously with both contact and non-contact, which involves ignoring non-contact signals from two or more different button modules that have received input within the same time.
According to clause 8,
When the control board receives input from two or more different button modules within a predetermined time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, the predetermined time A recognition method for a button device that can be used simultaneously in both contact and non-contact mode, which includes ignoring contact signals from two or more different button modules that have received input within the same time range.
A button recognition method using a button device capable of simultaneous contact and non-contact use according to any one of claims 1 to 4, comprising:
A step where the proximity sensor of the button module receives input,
A step where the touch switch of the button module receives input within a set time,
When the control board receives input from both the proximity sensor and the touch switch of the same button module within a set time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, A method of recognizing a button device that can be used simultaneously in contact and non-contact, including the step of performing control according to the contact signal.
A button recognition method using a button device capable of simultaneous contact and non-contact use according to any one of claims 1 to 4, comprising:
A step where the proximity sensor of the button module receives input,
A step where the touch switch of the button module receives input within a set time,
When the control board receives input from both the proximity sensor and the touch switch of the same button module within a predetermined time, among the non-contact signal generated when the proximity sensor detects an object and the contact signal generated when the touch switch is activated, A method of recognizing a button device that can be used simultaneously in contact and non-contact, including the step of performing control according to the non-contact signal.