TWM549492U - Intelligent building engineering equipment testing system - Google Patents

Description

Intelligent building engineering equipment debugging system

This creation involves the field of terminal technology, and in particular relates to a smart building engineering equipment debugging system.

With the rapid development of network technology, more and more products are becoming more intelligent, such as smart buildings. In the construction process of smart buildings, it is often necessary to install a large number of engineering equipment, such as intelligent switches, environmental monitors, access control and other engineering equipment.

In the prior art, the engineering personnel only installs the engineering equipment. After the installation is completed, the engineering equipment is connected with the control server, and the control server can obtain the identification number of the engineering equipment having the connection relationship. The post-debugging personnel can debug the engineering equipment through the control server, such as adjusting the corresponding parameters for each engineering equipment. However, because the control server only contains the identification number of the engineering equipment, it is difficult for the commissioning personnel to correspond each identification number with the actually installed engineering equipment. This requires the commissioning personnel to reach the actual installation location of the engineering equipment again to determine the correspondence between the identification number of each engineering device in the control server and the actually installed engineering equipment. In the project with a large number of engineering equipment installations, it will cost more labor costs and time costs, and the debugging efficiency of engineering equipment is lower.

The purpose of this creation is to provide a smart building engineering equipment commissioning system to reduce labor costs and time costs in the engineering equipment commissioning process of smart buildings, and improve the debugging efficiency of engineering equipment.

In order to solve the above technical problem, the present invention provides the following technical solutions: a smart building engineering equipment debugging system, including engineering equipment, a mobile debugging terminal for acquiring an identification number and an installation location of the engineering equipment, and the mobile debugging terminal A debug control device for wirelessly connecting and adjusting related parameters of the engineering device, wherein the mobile debug terminal includes at least a signal input component having a display screen and an operation button.

In a specific implementation of the present invention, the debugging control device includes a central server and a central controller, and the central server is respectively connected to the central controller and the mobile debugging terminal, and the central controller is The engineering equipment is connected to adjust related parameters of the engineering equipment.

In a specific implementation of the present invention, the debugging control device is provided with at least one communication interface of a CAN bus interface, an Ethernet interface, an RS485 interface, an RS232 interface, and an EtherCAT bus interface, through the CAN convergence. The interface, the Ethernet interface, the RS485 interface, the RS232 interface, or the EtherCAT bus interface are connected to the engineering device.

In a specific implementation of the present invention, the mobile debugging terminal further includes a signal processing component, a first communication component, and a second communication component, wherein the signal processing component and the signal input component are respectively the first a communication component coupled to the second communication component, the first communication component for connecting to the debug control device, the second communication component for The engineering device is connected, the signal input component is configured to receive an operation instruction input by an engineering staff, the signal processing component is configured to obtain an installation position of the engineering device according to the operation instruction; and transmit the second communication component Performing information interaction with the engineering device to obtain an identification number of the engineering device, and transmitting the identification number to the debugging control device through the first communication component.

In a specific implementation of the present invention, the second communication component includes at least one of a CAN bus interface, an Ethernet interface, an RS485 interface, an RS232 interface, and an EtherCAT bus interface.

In a specific implementation of the present invention, the second communication component further includes a universal serial bus interface for an external communication interface.

In a specific implementation of the present invention, the second communication component further includes a near field communication NFC communication module, an infrared IR communication module, and/or a Wi-Fi communication module.

In a specific implementation of the present invention, the mobile debugging terminal further includes an image collecting component, configured to capture a picture of the installation environment of the engineering device or scan the two-dimensional bar code information on the engineering device.

Applying the technical solution provided by the present embodiment, the mobile debugging terminal can obtain installation information such as the identification number and the installation location of the engineering device, and the debugging control device is connected with the mobile debugging terminal, and can receive the identifier of the engineering device sent by the mobile debugging terminal. After installing the engineering equipment, the commissioning control device can be connected with the engineering equipment to adjust the relevant parameters of the engineering equipment. During the installation of the engineering equipment, the commissioning control device obtains the installation information such as the identification number and installation location of the engineering equipment, and the commissioning personnel must pass the commissioning control device to the engineering. When the device performs parameter adjustment, the corresponding relationship between the identification number and the actually installed engineering equipment can be determined directly through the installation related information of the engineering equipment on the debugging control device, thereby determining which engineering equipment to adjust which parameters. Avoid the actual installation location to determine the corresponding relationship between the engineering equipment identification number and the actual engineering equipment, saving labor costs and time costs, and improving the debugging efficiency of engineering equipment.

100‧‧‧Debug control device

101‧‧‧Central Server

102‧‧‧Central controller

200‧‧‧Mobile debugging terminal

201‧‧‧Signal input unit

202‧‧‧Signal Processing Unit

203‧‧‧First communication unit

204‧‧‧Second communication unit

300, 1, 2, 3, 4, N‧‧‧ engineering equipment

In order to more clearly illustrate the technical means of the present embodiment, the drawings used in the description of the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the present invention. For those of ordinary skill in the art to which the present invention pertains, other drawings may be obtained from these drawings without the inventive effort.

1 is a schematic structural view of a smart building engineering equipment debugging system in the present embodiment; FIG. 2a is another structural schematic diagram of a smart building engineering equipment debugging system in the creative embodiment; FIG. 2b is a creative embodiment Another structural schematic diagram of the intelligent building engineering equipment debugging system; FIG. 3 is a schematic structural view of the front side of the mobile debugging terminal in the creative embodiment; FIG. 4 is a schematic structural view of the back side of the mobile debugging terminal in the creative embodiment; Figure is the intelligent building engineering equipment debugging system in the creation example Another structural schematic diagram of the intelligent building engineering equipment debugging system in the present embodiment; FIG. 7 is another structural schematic diagram of the intelligent building engineering equipment debugging system in the creative embodiment; The figure is another structural diagram of the intelligent building engineering equipment debugging system in the creative embodiment.

In order to better understand the present creative solution by those having ordinary knowledge in the technical field of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments. It is apparent that the described embodiments are only a part of the embodiments of the present invention, and not all of them. Based on the embodiments in the present creation, all other embodiments obtained by those skilled in the art in the art without the creative work are within the scope of the present invention.

Referring to FIG. 1 , FIG. 2 a , and FIG. 3 , the intelligent building engineering equipment debugging system provided by the present embodiment may include an engineering equipment 300, and a mobile debugging terminal for acquiring the identification number and installation location of the engineering equipment 300. 200. The debugging control device 100 is connected to the mobile debugging terminal 200 and configured to adjust related parameters of the engineering device 300. The mobile debugging terminal 200 includes at least a signal input unit 201. The signal input unit 201 includes a display screen and an operation button.

In the present creative embodiment, the intelligent building engineering equipment debugging system may include an engineering equipment 300, a mobile debugging terminal 200, and a debugging control device. 100. Figure 1 and Figure 2a show only one engineering equipment. In fact, the intelligent building engineering equipment debugging system can contain multiple engineering equipments, as shown in Figure 2b, which can be engineering equipment 1, engineering equipment 2,... The engineering equipment N, and the N engineering equipments may be one or more types of equipment, and the commissioning control device 100 can debug various types of engineering equipment.

The signal input component 201 included in the mobile debugging terminal 200 may include a display screen and an operation button for receiving an operation instruction input by an engineering personnel, such as an information description instruction input by an engineering personnel on an installation position of the engineering equipment 300, or an engineering equipment 300. Number editing instructions, etc.

During the installation process of the engineering device 300, the mobile debugging terminal 200 can acquire installation related information such as the identification number and the installation location of the engineering device 300. In an actual application, the engineer can hold the mobile debugging terminal 200 during the installation of the engineering device 300, establish a connection between the mobile debugging terminal 200 and the engineering device 300, and the mobile debugging terminal 200 can obtain the identification number of the engineering device 300, The received description signal of the engineering equipment 300 input by the engineering personnel constitutes installation related information of the engineering equipment 300. The installation related information includes at least the identification number and the installation location, and may also include a name, an installation image, and the like.

The initial sequence number of the engineering device 300 is the number set by the engineering device 300 at the time of shipment. The initial serial numbers of different engineering devices of the same type may be the same. For the sake of distinction, the present embodiment can determine the identification number of the engineering device 300 by: When the initial sequence number of the engineering device 300 read by the mobile debugging terminal 200 is insufficient to distinguish it from other engineering devices At this time, the engineering equipment 300 can be numbered by the engineering staff through the mobile debugging terminal 200, and the number is input into the engineering equipment 300, so that the initial serial number plus the number of the engineering equipment 300 can constitute the identification number of the engineering equipment 300. The identification number uniquely identifies an engineering device.

The mobile debugging terminal 200 can be connected to the debugging control device 100. After the related information is acquired, such as the identification number and the installation location of the engineering device 300, the installation control information can be sent to the debugging control device 100, such as the identification number and the installation location of the engineering device 300. .

After receiving the relevant information such as the identification number of the engineering device 300 and the installation location transmitted by the mobile debugging terminal 200, the debugging control device 100 can store the installation related information of the engineering device 300.

In practical applications, there may be multiple engineers performing installation operations on multiple engineering equipments at the same time. Each engineering personnel can hold a mobile debugging terminal 200, and each mobile debugging terminal 200 can obtain installation related information of the corresponding engineering equipment. And transmitting the acquired installation related information of the engineering equipment to the commissioning control device 100. Thereby, the commissioning control device 100 can obtain installation related information of a plurality of engineering equipments, as shown in FIG. 2b.

The installation process of the engineering equipment 300 by the engineering personnel is also a process of establishing the connection between the engineering equipment 300 and the commissioning control device 100. After the engineering equipment 300 is installed, the commissioning control device 100 can be connected with the engineering equipment 300 to obtain a connection engineering project. The identification number of the device 300. The identification number may uniquely identify the engineering device 300, which may be the initial identification number of the engineering device 300 itself, or may be the identification number edited by the mobile debugging terminal 200.

The debug control device 100 can associate the identification number of the connected engineering device 300 with the installation related information of the engineering device 300.

The debugging control device 100 can provide an interactive interface for the debugging personnel. The debugging personnel can query the installation control information of the engineering equipment 300 on the debugging control device 100. According to the installation related information of the engineering equipment 300, the debugging personnel can easily debug the engineering equipment in the control device 100. The identification number of 300 corresponds to the actually installed engineering equipment 300, and the engineering equipment 300 can be parameter-adjusted through the commissioning control device 100.

After receiving the parameter adjustment instruction of the engineering equipment 300 issued by the commissioning personnel based on the installation related information of the engineering equipment 300, the commissioning control device 100 can adjust the relevant parameters of the engineering equipment 300. For example, an environmental monitor is installed at both the position 1 and the position 2, and the temperature warning thresholds of the environmental monitors installed at different positions are different, and the commissioning personnel can set the environment according to the installation information of the environmental monitor in the debugging control device 100. The identification number of the monitor is associated with the actually installed environmental monitor, and different temperature warning thresholds are set for the environmental monitors at different locations.

It should be noted that the engineering personnel and the debugging personnel may be the same person or different people, and the present creative embodiment does not limit this.

Applying the system provided by the present embodiment, the mobile debugging terminal can obtain installation information such as the identification number and the installation location of the engineering device, and the debugging control device is connected with the mobile debugging terminal, and can receive the identification number of the engineering device sent by the mobile debugging terminal. Installation related information such as the installation location, after the installation of the engineering equipment is completed, the commissioning control device can be connected with the engineering equipment Connect and adjust the relevant parameters of the engineering equipment. During the installation process of the engineering equipment, the commissioning control device obtains the installation information such as the identification number and installation location of the engineering equipment. When the commissioning personnel wants to adjust the parameters of the engineering equipment through the commissioning control device, directly through the commissioning control equipment on the control device. The relevant information of the installation can determine the correspondence between the identification number and the actually installed engineering equipment, thereby determining which engineering equipment to adjust which parameters, and avoiding the actual installation location to determine the identification of the engineering equipment. The corresponding relationship between the number and the actual engineering equipment saves labor costs and time costs, and improves the debugging efficiency of engineering equipment.

As shown in FIG. 2a, in a specific implementation of the present invention, the debug control apparatus 100 may include a central server 101 and a central controller 102, and the central server 101 is connected to the central controller 102 and the mobile debugging terminal 200, respectively. The central controller 102 is coupled to the engineering device 300 for adjusting related parameters of the engineering device 300.

In the present embodiment, the central server 101 can be connected to the mobile debugging terminal 200, and specifically, can be connected to the mobile debugging terminal 200 through a wireless network. The mobile debugging terminal 200 can transmit the installation related information of the engineering device 300 to the central server 101 after acquiring the relevant information such as the identification number and the installation location of the engineering device 300 during the installation process of the engineering device 300. The central server 101 can also be coupled to the central controller 102. After the installation of the engineering equipment 300 is completed, the central controller 102 can be connected to the engineering equipment 300 to obtain the identification number of the installed engineering equipment 300. When the commissioning personnel needs to perform parameter adjustment on the installed engineering equipment 300, the engineering equipment 300 in the central server 101 can be obtained through the central controller 102. According to the installation related information, the commissioning personnel can easily associate the identification number of the engineering equipment 300 with the actually installed engineering equipment 300, and then adjust the parameters of the engineering equipment 300 in a targeted manner. .

At least one communication interface of the CAN bus interface, the Ethernet interface, the RS485 interface, the RS232 interface, and the EtherCAT bus interface can be set in the debug control device 100 to pass through the CAN bus interface, the Ethernet interface, the RS485 interface, and the RS232 interface. The interface or EtherCAT bus interface is connected to the engineering device 300.

As shown in FIG. 2a, in a specific implementation of the present invention, the mobile debugging terminal 200 may further include a signal processing component 202, a first communication component 203, and a second communication component 204, and the signal processing component 202 and the signal input component respectively. 201. The first communication component 203 and the second communication component 204 are connected. The first communication component 203 is for connecting to the debug control device 100, the second communication component 204 is for connecting to the engineering device 300, and the signal input component 201 is for receiving engineering. The operation command input by the personnel, the signal processing component 202 is configured to obtain the installation location of the engineering device 300 according to the operation instruction, and perform information interaction with the engineering device 300 through the second communication component 204 to acquire the identification number of the engineering device 300 and pass the first The communication unit 203 transmits to the debug control device 100.

In the present embodiment, the signal input component 201 included in the mobile debugging terminal 200 may include a display screen and an operation button for receiving an operation instruction input by an engineering personnel, such as an information description instruction input by the engineering personnel on the engineering device 300, or For the number editing instruction of the engineering equipment 300, The signal processing component 202 can obtain the installation location of the engineering equipment 300 according to the operation instruction. Specifically, the engineering personnel can input the specific installation location of the engineering equipment 300 through the signal input component 201, or by using the specific installation location of the engineering equipment 300. Like mode input. The information processing component 202 can obtain information such as the identification number and model number of the engineering device 300 through the information interaction between the second communication component 204 and the engineering device 300. The signal processing unit 202 can transmit the installation related information including the identification number and the installation position of the engineering equipment 300 to the commissioning control device 100 through the first communication unit 203.

The second communication component 204 can include at least one of a CAN bus interface, an Ethernet interface, an RS485 interface, an RS232 interface, and an EtherCAT bus interface. When one or more communication interfaces are provided in the engineering device, the mobile debugging terminal 200 can establish a connection with the engineering device 300 through a corresponding communication interface.

The second communication component 204 can also include a universal serial bus interface for an external communication interface, such as an external P-bus interface or a KNX interface.

The second communication component 204 may further include a Near Field Communication (NFC) communication module, an Infrared Radiation (IR) communication module, and/or a Wi-Fi communication module. When the one or more communication modules are provided in the engineering device 300, the mobile debugging terminal 200 can be connected to the engineering device 300 through a corresponding communication module.

In a specific implementation of the present invention, the mobile debugging terminal 200 may further include an image collecting component for capturing an installation environment picture of the engineering device 300 or scanning the two-dimensional bar code information on the engineering device 300. In reality In the inter-application, the two-dimensional bar code information may be marked on the engineering device 300 in advance, and the two-dimensional bar code information carries information such as the initial serial number of the engineering device 300.

As shown in FIG. 3 and FIG. 4, a liquid crystal display screen, a front camera lens, and operation buttons are disposed on the front side of the mobile debugging terminal 200, and a 3G/4G and Sub-1G interface are disposed on the right side, and a USB interface is disposed on the left side. The USB interface can be externally connected to P-bus, KNX, EtherCAT, M-bus, etc. According to XMPP (XMPP is a protocol based on the standard universal markup language-based XML), the top is provided with an IR communication module, and the top side is set. There is a rear camera lens with an NFC module in the middle and a CAN bus interface, RS485 interface, and Ethernet interface.

The following is an example of several typical engineering equipments, and the intelligent building engineering equipment debugging system provided by the present embodiment is described. Each engineering equipment is provided with a micro processing module for processing instructions, information, and the like.

(1) The engineering device 1 having a microprocessor module and an NFC module as shown in FIG. 5, wherein the microprocessor module and the NFC module are connected through an I ² C bus bar. During the installation of the engineering equipment 1, the engineer can scan the NFC code of the engineering equipment 1 by the mobile debugging terminal 200 to obtain the identification number of the engineering equipment 1. In addition, the engineering personnel can input relevant description information of the engineering equipment 1, such as the name of the equipment, the installation location, the installation personnel, the photo of the equipment, etc., and the related description information and the identification number constitute the installation related information of the engineering equipment 1, and the relevant information will be installed. The information is transmitted to the central server 101 via the Wi-Fi network, and the debugger can obtain the installation related information in the central server 101 through the central controller 102, and can further adjust the parameters of the engineering device 1 connected through the CAN bus. The engineering equipment 1 can be a smart switch, an environmental monitor, or the like.

(2) The engineering device 2 with the built-in microprocessor module as shown in Fig. 6 connects an external NFC-containing RFID device via Wiegand. The engineering equipment 2 is connected to the central controller 102 via Ethernet, and the engineering equipment 2 may be an access controller or the like.

During the process of installing the engineering device 2, the engineering staff can scan the NFC of the RFID device with the mobile debugging terminal 200 to obtain the serial number SN and the node ID of the engineering device 2. The engineer can edit the parameters of the engineering equipment 2 on the mobile debugging terminal 200, mark the name, installation location, surrounding environment and other information of the engineering equipment 2, and edit it and transmit it to the central server 101 through Wi-Fi.

During the debugging phase, the debugger obtains the installation related information received by the central server 101 through the central controller 102, and corresponds to the identification number of the engineering device in the central controller 102, and performs debugging, thereby saving time.

(3) The engineering device 3 incorporating the microprocessor module as shown in Fig. 7 is connected to the central controller 102 via Ethernet.

During the installation of the engineering equipment 3, the engineering personnel can connect the engineering equipment 3 with the mobile debugging terminal 200 by using Ethernet/CAN/RS485/RS232/EtherCAT/P-bus, and the engineering personnel can view the mobile debugging terminal 200 after the connection is completed. The related information of the engineering equipment 3 determines whether the engineering equipment 3 is connected to the central controller 102 smoothly, or has other problems. After the debugging is completed, the discovered problems and other information of the engineering equipment 3 are edited and transmitted through the Wi in the mobile debugging terminal 200. -Fi is sent to the central servo The central server 101 transmits information to the central controller 102 via the local area network. During the maintenance or debugging of the post-commissioning personnel, the information corresponding to the engineering equipment 3 and the existing problems can be visually read in the central controller 102, and corresponding processing is performed.

(4) As shown in Fig. 8, the engineering device 4 has a built-in microprocessor module and an IR module, wherein the microprocessor module and the IR module are connected through a UART. The engineering equipment 4 is connected to the central controller 102 via Ethernet. The IR device can be an infrared remote control or the like.

The engineer connects the IR device to the engineering device 4 through the IR, and then connects the IR device to the mobile debugging terminal 200 through the IR. The operation command and the device parameter information, such as the installation location and the surrounding environment, can be edited on the mobile debugging terminal 200. The engineering personnel transmits the operation command back to the IR device through the IR, and the IR device receives the edited operation command signal, and can control the engineering device 4 according to the learned instruction.

The engineer transmits the information related to the installation of the edited engineering equipment 4 to the central server 101 via Wi-Fi. In the commissioning phase, the commissioning personnel accurately control the engineering equipment 4 on the central controller 102 through the installation related information received by the central server 101.

The various embodiments in the specification are described in a gradual manner, and each embodiment is focused on differences from the other embodiments, and the same or similar parts between the various embodiments may be referred to each other.

A person skilled in the art will further appreciate that the elements and algorithm steps of the various examples described in connection with the embodiments disclosed herein can be implemented in electronic hardware, computer software, or a combination of both, in order to clearly illustrate the hard The interchangeability of the body and the software, the composition and steps of each example have been generally described in terms of function in the above description. Whether these functions are performed in hardware or software depends on the specific application and design constraints of the solution. The skilled person can use different methods to implement the described functions for a variety of specific applications, but such implementations should not be considered beyond the scope of this creation.

The steps of the method or algorithm described in connection with the embodiments disclosed herein may be implemented directly by hardware, a software module executed by a processor, or a combination of both. The software module can be placed in random memory (RAM), memory, read only memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, removable disk, A CD-ROM, or any other form of storage medium known in the art of the art.

The specific embodiments are applied herein to explain the principles and implementations of the present invention. The description of the above embodiments is only for helping to understand the technical solution of the present creation and its core ideas. It should be understood that, for those having ordinary knowledge in the technical field of the present invention, some modifications and modifications may be made to the present creation without departing from the principle of the present invention. These improvements and modifications also fall into the present claim. Within the scope of protection.

100‧‧‧Debug control device

200‧‧‧Mobile debugging terminal

201‧‧‧Signal input unit

300‧‧‧Engineering equipment

Claims (8)

A smart building engineering equipment debugging system includes: engineering equipment; a mobile debugging terminal, which is used for obtaining an identification number and an installation position of the engineering equipment, and at least includes a signal input component having a display screen and an operation button; and a debugging control device The wireless connection with the mobile debugging terminal is used to adjust related parameters of the engineering device. The smart building engineering equipment commissioning system of claim 1, wherein the commissioning control device comprises a central server and a central controller, wherein the central server is respectively connected to the central controller and the mobile debugging terminal, and The central controller is connected to the engineering device for adjusting related parameters of the engineering device. The intelligent building engineering equipment debugging system according to claim 1, wherein the debugging control device is provided with at least one of a CAN bus interface, an Ethernet interface, an RS485 interface, an RS232 interface, and an EtherCAT bus interface. The communication interface is connected to the engineering device through the CAN bus interface, the Ethernet interface, the RS485 interface, the RS232 interface, or the EtherCAT bus interface. The intelligent building engineering equipment debugging system according to any one of the preceding claims, wherein the mobile debugging terminal further comprises a signal processing component, a first communication component and a second communication component, wherein the signal processing a component is respectively connected to the signal input component, the first communication component, and the second communication component, the first communication component being used for the debug control a device is connected, the second communication component is configured to be connected to the engineering device, the signal input component is configured to receive an operation instruction input by an engineering personnel, and the signal processing component is configured to obtain an installation position of the engineering device according to the operation instruction; The second communication component interacts with the engineering device to obtain an identification number of the engineering device, and sends the identification number to the debugging control device. The intelligent building engineering equipment debugging system according to claim 4, wherein the second communication component comprises at least one of a CAN bus interface, an Ethernet interface, an RS485 interface, an RS232 interface, and an EtherCAT bus interface. interface. The intelligent building engineering equipment debugging system of claim 5, wherein the second communication component comprises a universal serial bus interface for an external communication interface. The smart building engineering equipment debugging system according to claim 6, wherein the second communication component comprises a near field communication NFC communication module, an infrared IR communication module and/or a Wi-Fi communication module. The intelligent building engineering equipment debugging system according to claim 4, wherein the mobile debugging terminal further comprises an image collecting component for capturing a picture of the installation environment of the engineering equipment or scanning the two-dimensionality on the engineering equipment. Barcode information.