CN112242906B

CN112242906B - Programmable communication device

Info

Publication number: CN112242906B
Application number: CN201910638483.0A
Authority: CN
Inventors: 余孟远
Original assignee: Xinyu Development Co ltd
Current assignee: Xinyu Development Co ltd
Priority date: 2019-07-16
Filing date: 2019-07-16
Publication date: 2022-08-23
Anticipated expiration: 2039-07-16
Also published as: CN112242906A

Abstract

A programmable communication device comprises a connecting unit, a near-end communication unit used for inputting communication parameters, a wireless communication unit suitable for communicating with a servo device and a control unit. The connection unit comprises a serial port adapted to receive the working data. The serial port is provided with at least two pins which are suitable for being electrically connected with two data cables of at least one working device. The communication parameters are at least used for setting a communication protocol. The control unit communicates with the at least one working device according to the communication parameters by using the same communication protocol, and transmits the working data to the servo device through the wireless communication unit according to a preset address. Therefore, the data cable is directly and electrically connected, and the communication parameters can be set by software programming, so that the invention can be universally used for working devices with different communication protocols, and can reduce the whole volume by a simplified structure, thereby improving the space benefit, the installation simplicity and the use convenience.

Description

Programmable communication device

Technical Field

The present invention relates to a communication device, and more particularly, to a programmable communication device.

Background

Generally, working devices installed outdoors, such as a camera for capturing images, an energy storage device for supplying electric energy, or other devices capable of generating image and audio signals, or generating a number change or a plurality of changes, transmit working data to a remote server through a data exchange device in order to transmit the working data such as image and audio signals, working time, number change or a plurality of changes.

However, in order to support the above-mentioned working devices, the data exchange equipment must include architectures such as a Call Agent (CA), a Media Gateway (MGW), and a Signal Gateway (SG), which are complicated in structure and quite large in size.

Importantly, the data exchange equipment must be matched with different working devices, has different specifications and poor applicability, and is not easy to maintain and replace when any one framework is abnormal.

Disclosure of Invention

The invention aims to provide a programmable communication device which can improve the space benefit, and improve the installation simplicity and the use convenience.

The programmable communication device is suitable for transmitting working data of at least one working device to a servo device, wherein the at least one working device is provided with two data cables, and the programmable communication device comprises a connecting unit, a near-end communication unit, a wireless communication unit and a control unit.

The connecting unit is suitable for receiving the working data and comprises a serial port, and the serial port is provided with at least two pins suitable for being electrically connected with the data cable.

The near-end communication unit is used for inputting communication parameters, and the communication parameters are at least used for setting a communication protocol.

The wireless communication unit is adapted to communicate with the server via a wireless communication technology.

The control unit is electrically connected with the near-end communication unit, the connection unit and the wireless communication unit, communicates with the at least one working device by the same communication protocol according to the communication parameters, and transmits the working data to the servo device through the wireless communication unit according to a preset address.

The programmable communication device comprises a near-end communication unit and a communication module, wherein the near-end communication unit comprises a connection port which is suitable for being connected with an external device and inputting the communication parameters.

In the programmable communication device of the invention, the connection port is a universal serial bus.

In the programmable communication device, the serial port is provided with four pins, and two pins form a group and form an included angle.

The wireless communication unit of the programmable communication device comprises a communication module which is connected with the internet through a mobile communication technology and is communicated with the servo device.

In the programmable communication device, the wireless communication unit further comprises an antenna electrically connected with the communication module and used for enhancing electromagnetic wave signals.

The programmable communication device of the invention is characterized in that the wireless communication unit is connected with the internet through a wireless local area network technology and is a communication module which is communicated with the servo device.

The communication parameters of the programmable communication device are further used for setting an account number and a password of an online internet and an address for connecting the servo device.

The invention has the beneficial effects that: the invention can be used for working devices with different communication protocols, and can reduce the whole volume by simplifying the structure, thereby improving the space benefit, the installation simplicity and the use convenience.

Drawings

Other features and effects of the present invention will become apparent from the following detailed description of the embodiments with reference to the drawings, in which:

FIG. 1 is a perspective view of one embodiment of a programmable communication device of the present invention;

FIG. 2 is a schematic illustration of the embodiment;

FIG. 3 is a block diagram of the described embodiment; and

fig. 4 is a schematic diagram illustrating a setting interface in the embodiment.

Detailed Description

Referring to fig. 1, 2 and 3, an embodiment of the programmable communication device 1 of the present invention is adapted to transmit an operation data D of an operation device 2 to a servo device 3. In the present embodiment, the working device 2 is installed in a case and includes a camera 21 for capturing images and an inverter 22 electrically connected to the camera 21. The inverter 22 has two data cables 221. The working data D may be related data such as video signals or working time.

It should be noted that the working device 2 is not limited to include the camera 21, but may also include an energy storage device for supplying power, or other devices capable of generating video and audio signals, or generating quantity changes and times changes, and when the working device 2 includes an energy storage device, the working data D may be data of electric energy collection amount/unit time, electric energy supply amount/unit time, and the like.

In addition, the case refers to an area divided by the work place where the work device 2 is installed, the number of cases in each work place is not limited to one, and in other variations of the present embodiment, 2 cases or more than 2 cases may be provided, and at least one inverter 22 is provided for each case, the inverter 22 has a unique identification code, and a plurality of inverters 22 can be connected in series.

The programmable communication device 1 comprises a connection unit 11, a near-end communication unit 12, a wireless communication unit 13, and a control unit 14.

The connection unit 11 is adapted to receive the working data D and comprises a serial port 111. The serial port 111 has four pins 112 adapted to electrically connect to the data cable 221. The two pins 112 are a set and form an included angle. In this embodiment, the included angle is 90 degrees, so that the pin 112 can be electrically connected to the data cable 221 inserted along the horizontal direction, or electrically connected to the data cable 221 inserted along the vertical direction.

The near-end communication unit 12 is used for inputting a communication parameter S and includes a connection port 121 adapted to connect an external device. In the present embodiment, the connection port 121 is a Universal Serial Bus (USB). The communication parameters S are used to set the inverter brand, account and password for connecting to the internet, address P for connecting to the server 3, the number of cases, the number of inverters, and the communication protocol. The communication protocol may be a protocol conforming to serial interface standards such as RS232, RS485, RS422, RJ45, USB, or type C. In this embodiment, the external device may be the server 3 or other computer, and the communication parameter S is edited by the external device through a setting interface 4 (as shown in fig. 4) after being connected to the external device.

The wireless communication unit 13 is adapted to communicate with the servo device 3 via wireless communication technology. In the embodiment, the wireless communication unit 13 includes a communication module 131 connected to the internet via mobile communication technology (mobile phone communication technologies) and communicating with the server 3, and an antenna 132 electrically connected to the communication module 131 and used for enhancing electromagnetic wave signals. The mobile communication technology can be 3G, 4G or 5G.

It should be noted that the communication module 131 is not limited to being connected to the internet through a mobile communication technology, and in other variations of the present embodiment, the communication module may be connected to the internet through a Wireless local area network (wlan) technology.

The control unit 14 is electrically connected to the near-end communication unit 12, the connection unit 11 and the wireless communication unit 13, communicates with the working device 2 according to the communication parameter S with the same communication protocol, and transmits the working data D to the server 3 through the wireless communication unit 13 according to a preset address P.

Before installation, the communication parameters S can be edited through the setting interface 4 (as shown in fig. 4) by matching with the communication protocol of the working device 2 and connecting to the external device through the connection port 121 of the near-end communication unit 12, so as to set the communication protocol. Therefore, when the connection port 121 receives the communication parameter S, the control unit 14 updates the communication protocol according to the communication parameter S.

Referring to fig. 3 and 4, the setting interface 4 includes a serial port selection field 41 for determining the serial port type of the connected external device, an inverter selection field 42 for determining the brand of the inverter 22, two account setting fields 43 for setting account numbers and passwords for the internet, two address setting fields 44 for determining the address P, a case number setting field 45 for setting a case number to identify a case, a case number setting field 46 for setting the number of cases, a project field 47 for setting the number of inverters in each case, a time setting field 48 for setting the interval time for returning the operation data D, and a plurality of code setting fields 49 for determining the communication protocol. It should be noted that fig. 4 is only an exemplary schematic diagram of the operation process, different from the example illustrated in the following paragraphs.

For example, when the external device sets the communication parameter S, it first sets the serial port type to COM4 through the serial port selection column 41 of the setting interface 4, then selects the brand of the inverter 22 through the inverter selection column 42, and then sets the account number and password of the internet through the account setting column 43, at this time, the external device automatically updates the address P of the address setting column 44 and updates the code of the code setting column 49 according to the selected inverter 22, and then sets the number of the case through the case number setting column 45, such as a73006602, and sets the number of cases through the case number setting column 46, such as 3 cases, sets the number of inverters in each case through the item column 47, such as 3 cases, 6

inverters

22, and 2 inverters 22 in each case, the entry column 47 is set to 06-02-02-02, where the first set of numbers 06 is the total number of inverters 22, the second set of numbers is the number of inverters 22 in the first scenario, the third set of numbers is the number of inverters 22 in the second scenario, and the fourth set of numbers is the number of inverters 22 in the third scenario. Finally, the time for receiving the operation data D transmitted by each inverter 22 is set through the time setting column 48, for example, 60 seconds, so as to complete the setting of the communication parameter S.

During installation, the data cable 221 of the working device 2 is only required to be directly inserted into any group of pins 112 of the connecting unit 11, and installation is completed.

It should be noted that the programming for setting the communication parameter S is not limited to setting before installation, and may be set after installation according to practical requirements.

During communication, the control unit 14 communicates with the working device 2 according to the communication parameter S with the same communication protocol, receives the working data D through the serial port 111 of the connection unit 11, connects to the internet through the communication module 131 of the wireless communication unit 13, and transmits the working data D to the server 3 according to the address P. Therefore, the servo device 3 can monitor at a remote end to obtain video and audio signals or related data which can generate quantity change and frequency change.

From the above description, the advantages of the foregoing embodiments can be summarized as follows:

1. by directly electrically connecting the data cable 221 and setting the communication parameter S through software programming, the present invention can be generally used for working devices 2 with different communication protocols, can be simplified in structure to reduce the volume, can be suitable for various working devices 2, does not occupy space, and can further improve the space benefit.

2. And importantly, the installation is completed only by connecting the data cable 221 with the connecting unit 11, and when an abnormality occurs, the data cable can be replaced immediately, so that the installation is simple and convenient, the replacement is convenient, and the use convenience can be greatly improved.

The above description is only an example of the present invention, and the scope of the present invention should not be limited thereby, and the invention is still within the scope of the present invention by simple equivalent changes and modifications made according to the claims and the contents of the specification.

Claims

1. A programmable communication device adapted to transmit operation data of at least one operating device to a servo device, the at least one operating device having two data cables, the programmable communication device comprising:

the connecting unit is suitable for receiving the working data and comprises a serial port;

the near-end communication unit is used for inputting communication parameters, and the communication parameters are at least used for setting a communication protocol;

the wireless communication unit is suitable for communicating with the servo device through a wireless communication technology; and

the control unit is electrically connected with the near-end communication unit, the connecting unit and the wireless communication unit;

the method is characterized in that:

the serial port of the connecting unit is provided with at least two pins suitable for being electrically connected with the data cable, the control unit communicates with the at least one working device according to the communication parameters by using the same communication protocol, and transmits the working data to the servo device through the wireless communication unit according to a preset address.

2. A programmable communications device as in claim 1 wherein: the near-end communication unit comprises a connection port which is suitable for being connected with an external device and inputting the communication parameters.

3. A programmable communication device as in claim 2 wherein: the connection port is a universal serial bus.

4. A programmable communications device as in claim 1 wherein: the serial port is provided with four pins, and two pins are a group and form an included angle.

5. A programmable communications device as in claim 1 wherein: the wireless communication unit comprises a communication module which is connected with the internet through a mobile communication technology and is communicated with the servo device.

6. A programmable communications device as in claim 5 wherein: the wireless communication unit also comprises an antenna which is electrically connected with the communication module and is used for enhancing electromagnetic wave signals.

7. A programmable communications device as in claim 1 wherein: the wireless communication unit comprises a communication module which is connected with the internet through a wireless local area network technology and is communicated with the servo device.

8. A programmable communication device as in claim 7 wherein: the communication parameters are further used for setting an account number and a password of an online internet and for connecting an address of the servo device.