TWM575894U - Human-machine interface device - Google Patents

Abstract

The present invention relates to a human-machine interface device, including a commercial touch area, a photovoltaic touch area, a battery touch area, a load touch area, a plurality of circuit areas, and a control status display area. Through the different touch areas, the composition of the paths and circuits, and the description of the corresponding display areas, the solar energy storage device for intelligent energy management is installed in different positions according to the needs of the user, and is effectively executed. The operation of the human-machine interface greatly enhances the convenience of use. In particular, it can provide the user with an immediate and clear understanding of the current power supply state and power consumption state, and allow the user to adjust the power that can be used by the load, thereby effectively improving the use efficiency of the solar inverter energy storage device.

Description

Human-machine interface device

The present invention relates to a human-machine interface device, and more particularly to a human-machine interface device for an off-grid solar inverter energy storage device that intelligently displays an energy management state.

The existing conventional solar inverter energy storage device is often used in the production of human-machine interface, or uses a conventional LED display screen, or uses a seven-segment display digital display to achieve the current power digital content, for use in a variety of The intelligent management system of the intelligent off-grid solar inverter energy storage system with different sources of power supply and corresponding to different states is obviously insufficient; even worse, no human-machine interface device has been proposed. It is used for the intelligent power supply status display of solar inverter energy storage devices of various models, which needs to be improved and necessary.

The present invention discloses a human-machine interface device as a touch-type display control device, which can perform different touch control operations and control operations, and can be used for solar energy, in addition to being able to perform different control screen display and power operation state display. In the inverter energy storage system, the power required for the load is effectively provided. At the same time, this creation can be used for intelligent energy management of the solar inverter energy storage device, according to the user's needs to be installed in different positions, effectively implement the operation of the human-machine interface, greatly improving the convenience of use, especially Providing the user with instant and clear knowledge of the current power state and power state of the system, thereby adjusting the power that can be used by the load, thereby effectively improving the efficiency of the solar inverter energy storage device.

The human-machine interface device of the present invention is used in a solar inverter energy storage system. The human-machine interface device includes: a mains touch area, the mains touch area displays a mains pattern, and performs a mains touch display; a photovoltaic touch area, the photovoltaic touch area displays a photovoltaic pattern, and performs a photovoltaic touch Display; a battery touch area, the battery touch area displays a power supply pattern, and performs a battery touch display; a load touch area, the load touch area displays a load pattern, and performs a load touch display; a plurality of circuit areas Provided between the power touch area, the photovoltaic touch area, the battery touch area, and the load touch area, and a plurality of paths are correspondingly arranged to each other as a status display of the power path; and A control state display area is disposed on one side of the human-machine interface device, and displays the operation states of different power sources in a text manner, and can perform text touch input control.

10‧‧‧Human Machine Interface Device

11‧‧‧Power Touch Area

12‧‧‧Photovoltaic touch area

13‧‧‧Battery touch area

14‧‧‧Load touch area

15‧‧‧First Circuit Area

16‧‧‧Second circuit area

17‧‧‧ Third Circuit Area

18‧‧‧Control status display area

20‧‧‧ human-machine interface control device

21~24‧‧‧First~fourth button

25~27‧‧‧first to third indicator

30‧‧‧Human Machine Interface Control Unit

31~36‧‧‧First~Sixth button

37‧‧‧Switch button

41~46‧‧‧first to sixth indicator lights

50‧‧‧ human-machine interface control device

51~54‧‧‧first to fourth touch zone

55‧‧‧Touch display area

a~h‧‧‧first to eighth path

1 is a schematic diagram of a first embodiment of the present invention; FIG. 2 is a schematic diagram of a touch power touch area in the first embodiment of the present invention; FIG. 3 is a schematic diagram of a touch photovoltaic touch area in the first embodiment of the present invention; 4 is a schematic view of a touch cell touch area in the first embodiment of the present invention; FIG. 5 is a schematic view of the second embodiment of the present invention; FIG. 6 is a schematic view of the third embodiment of the present invention; Schematic diagram in the fourth embodiment.

The exemplary embodiments are described more fully hereinafter with reference to the accompanying drawings However, the concept of the present invention may be embodied in many different forms and should not be construed as being limited to the illustrative embodiments set forth herein. Rather, these exemplary embodiments are provided so that this description will be thorough and complete, and the scope of the inventive concept will be fully conveyed to those skilled in the art. In the figures, the size and relative size of the various touch areas may be exaggerated for clarity, and like numerals always indicate similar elements.

It should be understood that although terms, front, back, up, down, left or right, etc. may be used herein to describe the location of various components, such components are not to be construed as being limit. These terms are used to clearly distinguish one element from another and the different positions. Therefore, the upper and lower parts discussed below may be referred to as lower and upper; the left (or right) elements may be referred to as left (or right) elements without departing from the teachings of the inventive concept; as used herein, "first" or " The terms "second" and the like are used to clearly distinguish one element from another, and there is no necessarily a certain order relationship between the two. In addition, the terms "at least one", "plural" or "plurality" may be used herein to describe a plurality of elements having a single or more, but the plural elements are not limited to one, two, three or four. The number of more than one component represents the technology implemented. The explanation of these terms is explained first.

Please refer to FIG. 1 , which is a schematic diagram of an embodiment of the human-machine interface device 10 . The human-machine interface device 10 is a control device for touch display, which can perform different control screen display and power operation status display. In addition, and being able to perform user touch operation and control, it is used in a solar inverter energy storage system, which is an AC power source and solar energy (photovoltaic energy) simultaneously with the commercial power supply. The batteries and the like are electrically connected to each other to provide a power source required for the load. For example, the solar inverter energy storage system can provide an AC power source, a lighting device, or an electrical device for general household use.

The human interface device 10 of the present invention includes: a commercial touch area 11, a photovoltaic touch area 12, a battery touch area 13, a load touch area 14, a plurality of circuit areas 15, 16, 17 and a control status display area 18. However, we must emphasize that the arrangement pattern shown in Figure 1 is only for reference in the present example. In practice, the user can adjust according to his own needs or according to his own design. Different pattern arrangements are designed to enhance the convenience and aesthetics of the operation of the human interface device 10. The utility touch area 11 displays a representative image of a mains and can perform a commercial touch display of the user; the photovoltaic touch area 12 not only displays a representative image of the photovoltaic, but also provides a user with the ability to perform a photovoltaic touch. Controlled display; the battery touch area 13 not only displays the mains pattern, but also allows the user to perform a battery touch display; the load touch area 14 is a representative pattern of the display load. The same is the corresponding display that can perform load touch.

FIG. 1 further includes a display of a plurality of circuit areas disposed between the commercial touch area 11, the photovoltaic touch area 12, the battery touch area 13, and the load touch area 14, for correspondingly displaying the solar energy. The operating states of the relevant inverter circuits in the inverter energy storage system are provided with a plurality of paths corresponding to each other as a path state indicating the current power transmission. The plurality of circuits includes a first circuit region 15, a second circuit region 16, and a third circuit region 17, which are corresponding to the first circuit region 15, the second circuit region 16, and the third circuit region 17 described in the present application. For the operation mode of the inverter circuit, including but not limited to boost type, step-down type, buck-boost type, flyback type, feedforward control, half bridge type, full bridge type, AC/DC, DC/AC or The inverter circuit of DC/DC type is not limited in the implementation of this creation. In the illustration of FIG. 1, the first circuit area 15 is an AC/DC inverter, the second circuit area 16 is a DC/DC inverter, and the third circuit area 17 is a DC/AC inverter; however, for the actual Users can also switch to other forms of inverter circuits depending on their own circuit design requirements.

In Figure 1, a plurality of paths are displayed between different circuit areas, power supply sources, and loads. The first path a is transmitted from the mains touch area 11 to the path between the load touch areas 14, the second path b is transmitted from the mains touch area 11 to the first circuit area 15, and the third path c is determined by the photovoltaic The touch area 12 is transferred to the second circuit area 16, and the fourth path d is transferred from the battery touch area 13 to the third circuit area 17, and the fifth path e is transferred from the first circuit area 15 to the second circuit area 16, The sixth path f is transmitted from the second circuit area 16 to the third circuit area 17, the seventh path g is transmitted from the second circuit area 16 to the battery touch area 13, and the eighth path h is transmitted by the third circuit area 17. To the load touch area 14. When the solar inverter energy storage system is operated, the instantaneous state of different power supply sources will pass through different transmission paths, showing which different power supply power is supplied to the load or the battery is charged, thereby using The person can clearly know the current operational status of the solar inverter energy storage system.

The human interface device 10 further includes a control status display area 18, which is set On one side of the human-machine interface device 10, for example, the right side, the present invention is not limited to being disposed on the right side, and can be implemented on the left side, the upper side, or the lower side. The control state display area 18 mainly displays the operation state of different power supply to the load and the battery charging in a text manner, and allows the user to directly touch the control state display area 18 to perform the control of the text touch input. For example, in a normal display, the control status display area 18 can display a state that is currently different from the mains supply, the photovoltaic power supply, the battery charge, and/or the load supply.

On the other hand, in the right side of the housing of the human interface device 10 in FIG. 1, a plurality of jacks (not labeled) are provided for providing signals for plugging external devices, and the creation does not limit the human interface device. 10 types that can be plugged into different signals.

As shown in FIG. 2, when the user touches the mains touch area 11, the power status word and number related to the mains power supply are displayed in the control status display area 18, for example, the utility output is 100W, and the battery is charged. 40W and / or load power consumption 50W and so on. In the control state display area 18, the user can be directly input with the stylus or finger touch to input the target number to be controlled, so as to control the solar inverter energy storage system as a whole to achieve the required operation state. On the other hand, the mains touch area 11 will correspond to a prominent display, and the highlight display can be a flashing type. The battery touch area 13 and the load touch area 14 associated with the mains power supply are displayed in a conspicuous manner, and at the same time, the first path a, the second path b, and the fifth, sixth, and seventh paths are simultaneously displayed. e, f, g will also be displayed at the same time. In this way, the user can clearly know the current power supply and usage status of the mains.

As shown in FIG. 3, when the user touches the photovoltaic touch area 12, the power status words and numbers related to the photovoltaic power supply are displayed in the control status display area 18, for example, the photovoltaic output is 80W. The battery is charged 30W and/or the load consumes 40W and so on. In addition, the control state display area 18 in FIG. 3 can provide the user to directly input the target number to be achieved by using a stylus or a finger touch, and can control the solar inverter energy storage system to further achieve the required operation state. . On the other hand, the photovoltaic touch area 12 will correspond to a conspicuous display, and this eye-catching display can be practically The flashing pattern is considered, or the photovoltaic touch area 12 is in a particularly bright state. Furthermore, the battery touch area 13 and the load touch area 14 related to the photovoltaic power supply are also displayed conspicuously, and at the same time, the third path c, the sixth, seventh, and eighth paths f, g , h, will also be displayed at the same time. In this way, the user can clearly know the current state of power supply and/or use status of the photovoltaic power source.

Referring to FIG. 4, when the user touches the battery touch area 13, the control state display area 18 correspondingly displays the power status words and numbers related to the battery power supply, for example, the battery capacity is 80%. , battery charging 0W, battery output 30W and / or load power consumption 20W and so on. The control state display area 18 in FIG. 4 can simultaneously provide the user to directly input the desired target number by means of a stylus or a finger touch, and can control the solar inverter energy storage system to further achieve the required load operation. status. On the other hand, the battery touch area 13 corresponds to a conspicuous display, and the eye-catching display can be a flashing type in practice, or the battery touch area 13 is in a particularly bright state. Moreover, the load touch area 14 related to the battery power supply is also displayed conspicuously, and at the same time, the fourth path d and the eighth path h are simultaneously displayed. In this way, the user can clearly know the current power supply status and/or usage status of the battery power supply.

In an embodiment, after the load touch area 14 is touched, corresponding to the control status display area 18, the power status words and numbers related to the power source of the load and the load are displayed, for example, currently The load consumes 40W, which is 20W powered by photovoltaics, and 20W by battery. And can provide the user can directly input the desired target number to control the operation state of the solar inverter energy storage system as a whole to achieve the load.

As shown in FIG. 5, the human interface device 10 disclosed in FIG. 1 is applied to a human-machine interface control device 20, and the hardware device of the human-machine interface device 10 is directly attached to the human-machine interface control device 20. Medium and display the picture. The device itself and the function of the human interface device 10 after the installation is the same as the embodiment of the human interface device 10 of FIG. 1 , and also includes the main control touch area 11 for performing the mains touch display. The photovoltaic touch area 12 is configured to perform display of the photovoltaic touch; the battery touch area 13 also performs battery touch display; and the load touch area 14 performs load touch display. There are also a plurality of circuit areas 15, 16, 17 disposed between the commercial touch area 11, the photovoltaic touch area 12, the battery touch area 13 and the load touch area 14, and corresponding to each other. The paths a~h are used as the display of the power supply state or the load power consumption state of different power supply paths. And a control state display area 18, which is also disposed on one side of the human-machine interface device 10, displays the operation state of different power sources in a text manner, and allows the user to perform control and setting of the text touch input.

The human-machine interface control device 20 shown in FIG. 5 includes a plurality of buttons, such as first to fourth buttons 21 to 24, in addition to the human-machine interface device 10. The buttons 21 to 24 are disposed under the human interface device 10, and in an embodiment are arranged in a row, and the first to fourth buttons 21 to 24 can perform corresponding control. The human interface device 10; for example, in an embodiment, when the user presses the first button 21, the user can touch the touch function of the touch panel 11 of the mains touch area, but in practice, press the first The button 21 can also correspond to the load touch area 14 or other operations controlling the solar inverter energy storage system according to the user's needs, and the creation is not limited. At the same time, the human-machine interface control device 20 further includes a plurality of indicator lights, which are the first to third indicator lights 25~27, which are disposed between the first to fourth buttons 21~24 and the human-machine interface device. Between 10, the main function is to display the action state after the first to fourth buttons 21~24 are pressed, and correspondingly display different indicator colors to represent different operating states.

As shown in FIG. 6, the human interface device 10 disclosed in FIG. 1 is applied to a human-machine interface control device 30, and the hardware of the human-machine interface device 10 is directly installed into the human-machine interface control device 30. And the screen is displayed. The device itself and its function of the human-machine interface device 10 after the installation is the same as the embodiment of the human-machine interface device 10 of FIG. 1, and also includes the display of the commercial touch panel 11 to perform the commercial touch; The control area 12 is configured to perform display of the photovoltaic touch; the battery touch area 13 also performs display of the battery touch; and the load touch area 14 performs display of the load touch. with There are a plurality of circuit areas 15, 16, 17 disposed between the main control touch area 11, the photovoltaic touch area 12, the battery touch area 13 and the load touch area 14, and corresponding to each other. The paths a~h are used as the display of the power supply state or the load power consumption state of different power supply paths. The control state display area 18 is also disposed on one side of the human-machine interface device 10, and displays the operation state between different power sources in a text manner, and allows the user to perform control and setting of the text touch input.

The human-machine interface control device 30 in FIG. 6 further includes a plurality of buttons, which are first to sixth buttons 31 to 36, and first to third buttons 31 to 33 are disposed on the left side of the human interface device 10, and the fourth to the third The six buttons 34 to 36 are disposed on the right side of the human interface device 10, and the arrangement on both sides is a structure arranged in a line. For the functions of the first to sixth buttons 31 to 36, the human interface device 10 can be correspondingly executed. For example, in an embodiment, when the user presses the fourth button 34, the user can touch the touch. The touch function of the touch control area 14 is applied, but in practice, pressing the sixth button 36 can also correspond to the load touch area 14 or directly enter the power saving mode according to the user's needs, or other control of the solar reverse This creation is not limited to the operation of the energy storage system. At the same time, the human-machine interface control device 30 further includes a plurality of indicator lights, which are the first to sixth indicator lights 41 to 46, respectively. The first to third indicator lights 41 to 43 are disposed between the first to third buttons 31 to 33 on the left side and the human interface device 10, and the fourth to sixth indicator lights 44 to 46 are disposed on the right side. The fourth to sixth buttons 34 to 36 are connected to the human interface device 10. The first to sixth indicator lights 41 to 46 are mainly used to display different operating states of the different colors after the first to sixth buttons 31 to 36 are pressed.

The embodiment shown in FIG. 7 is to apply the human-machine interface device 10 disclosed in FIG. 1 to a human-machine interface control device 50, mainly to directly mount the hardware of the human-machine interface device 10 to the human-machine interface control device 50. Among them, the screen is displayed. FIG. 7 is basically the same as the embodiment of FIG. 6. The difference is that the human-machine interface control device 50 shown in FIG. 7 further includes a touch-sensitive display area 55 disposed under the human-machine interface device for display by touch pressure. The area 55 includes a plurality of touch zones, which are first to fourth touch zones 51-54, respectively, for displaying the human-machine interface control device 50 and solar energy inverse Different control operation options for communication and operation control between energy storage systems, such as Bluetooth wireless communication operation, Wi-Fi wireless communication operation, USB single button update setting operation, or remote server Computer control operations, etc., this creation is not limited. And the user can also perform the control and operation between the solar inverter energy storage system and the outside by directly contacting the first to fourth contact regions 51 to 54.

The embodiment of the human-machine interface control device 50 shown in FIG. 6 and FIG. 7 further includes a switch button 37 disposed on the lower side of the human-machine interface device 10 to provide direct access to the solar inverter energy storage system. The action to turn it on or off directly.

In summary, the present invention discloses a human-machine interface device, which can be configured with an intelligent energy management solar energy storage device through the composition of the different touch regions, paths and circuits, and the description of the corresponding display regions. According to the user's needs, the device is installed in different positions, effectively performing the operation of the human-machine interface, greatly improving the convenience of use, and in particular, providing the user with a clear and instant knowledge of the current power supply state and power consumption state of the system. By maneuvering the amount of power that can be used by the load, the efficiency of the solar inverter energy storage device is effectively improved. It is obvious that the technical content of this creation has extremely strong patent application requirements.

The contents described in this written description are merely illustrative of the preferred embodiments, and are not intended to limit the scope of the present invention, any related local variations, minor modifications, or additions, or digital or location. The changes, etc., are still outside the scope of this creation.

Claims (10)

A human-machine interface device is used in a solar inverter energy storage system, the human-machine interface device includes: a mains touch area, the mains touch area displays a mains pattern, and performs a mains touch display; a photovoltaic touch a control area, the photovoltaic touch area displays a photovoltaic pattern, and performs a photovoltaic touch display; a battery touch area, the battery touch area displays a power supply pattern, and performs a battery touch display; and a load touch area, the load touch The control area displays the load pattern and performs the load touch display; the plurality of circuit areas are disposed between the mains touch area, the photovoltaic touch area, the battery touch area, and the load touch area, and mutually Correspondingly, a plurality of paths are provided for displaying the status of the power path; and a control status display area is disposed on one side of the human-machine interface device to display the operation status of different power sources in a text manner, and can perform text touch Control of input control. The human interface device of claim 1, wherein the plurality of circuit areas include: a first circuit area, between the mains touch area and the first circuit area, a second path; the mains Between the touch area and the load touch area, a first path; the second circuit area, between the photovoltaic touch area and the second circuit area, is a third path; the first circuit area and the Between the second circuit area, a fifth path; a second path between the second circuit area and the battery touch area; and a third circuit area, the battery touch area and the third circuit area Between the second circuit area and the third circuit area, a sixth path; between the third circuit area and the load touch area, is an eighth path. The human-machine interface device of claim 2, wherein after the touch panel is touched, the power status word and number related to the mains power supply are displayed in the control status display area; and the user can provide Directly inputting a desired target number to control the solar inverter energy storage system as a whole to achieve a desired operational state; and the mains touch area corresponds to a conspicuous display and the battery touch area and the load touch area related to the mains power supply The first path, the second path, and the fifth, sixth, and seventh paths are also displayed. The human interface device of claim 2, wherein after the touch area is touched, the power status word and number related to the photovoltaic power supply are displayed in the control status display area; and the user can provide Directly inputting a desired target number to control the solar inverter energy storage system as a whole to achieve a desired operational state; and the photovoltaic touch area corresponds to a conspicuous display and the battery touch area associated with the photovoltaic power supply and the load touch area It will be displayed, and the third path and the sixth to eighth paths are also displayed at the same time. The human interface device of claim 2, wherein after the touch area of the battery is touched, the power status words and numbers related to the battery power supply are displayed in the control status display area; and the user can provide Directly inputting a desired target number to control the solar inverter energy storage system as a whole to achieve a desired operational state; and the battery touch area corresponding to a prominent display and the battery-powered load touch area will be displayed, and The fourth path and the eighth path are also displayed simultaneously. The human interface device of claim 2, wherein the load control area is touched, and the power status word and number related to the power source of the load power and the load are correspondingly displayed in the control status display area. And provide the user to directly input the desired target number to control the operation state of the solar inverter energy storage system as a whole to achieve the load. A human-machine interface control device is used in a solar inverter energy storage system, the human-machine interface device comprises: a human-machine interface device, the human-machine interface device comprises: a power touch area, the main touch area displays a power supply pattern, and performs a power touch display; a photovoltaic touch area, the photovoltaic touch area displays a photovoltaic pattern, and performs a photovoltaic touch display; a battery touch area, The battery touch area displays a power supply pattern and performs a battery touch display; a load touch area, the load touch area displays a load pattern, and performs a load touch display; and a plurality of circuit areas are set between the power touch a region, the photovoltaic touch area, the battery touch area, and the load touch area, and a plurality of paths corresponding to each other are displayed as a status of the power path; and a control status display area is provided One side of the human-machine interface device displays the operation state of different power sources in text mode, and can perform control of text touch input; a plurality of buttons are arranged under the interface of the human interface and arranged in a row, The buttons correspond to the human interface device, a user presses the different buttons to perform different operations in the human interface device; and a plurality of indicators are set between the buttons and Between a human interface device for displaying the operation state of the plurality of buttons is pressed. A human-machine interface control device is used in a solar inverter energy storage system, the human-machine interface device comprises: a human-machine interface device, the human-machine interface device comprises: a commercial touch area, the power touch area Displaying a mains pattern and performing a mains touch display; a photovoltaic touch area, the photovoltaic touch area displays a photovoltaic pattern, and performs a photovoltaic touch display; a battery touch area, the battery touch area displays a commercial power pattern, and executes Battery touch display; a load touch area, the load touch area displays a load pattern, and performs a load touch display; a plurality of circuit areas are disposed between the power touch area, the photovoltaic touch area, the battery touch area, and the load Between the touch areas, a plurality of paths are correspondingly arranged to each other as a status display of the power path; and a control status display area is disposed on one side of the human-machine interface device to display different power sources in a text manner The operation state, and can perform the control of the text touch input; a plurality of buttons are arranged in the row on the left and right sides of the interface device, and the buttons control the human interface device, and the user presses The different buttons are used to perform different operations in the human interface device; and a plurality of indicator lights are disposed between the buttons on the left and right sides and the human interface device to display that the buttons are pressed After the action state. The human interface control device of claim 8, further comprising a touch display area disposed under the human interface device, wherein the touch display area includes a plurality of touch areas for displaying the person Different control operation options for communication and control between the machine interface control device and the solar inverter energy storage system, and the user performs direct contact between the touch pressure regions to perform execution between the solar inverter energy storage system and the external Operation. The human-machine interface control device of claim 8, further comprising a switch button disposed on a lower side of the human-machine interface device to provide an action of the user to perform the opening or closing of the solar inverter energy storage system.