KR20220124575A - Network Apparatus Having TAP Function for Collecting Control Signal on the Network for Smart Factory - Google Patents

Abstract

Disclosed is a network apparatus having a network tap function for collecting a control signal on a network for a smart factory. The network apparatus of the present invention is implemented as a single apparatus in a miniaturized and integrated form, so it is possible to mirror a packet without a decline in speed or loss of network traffic and integrally change and reflect a traffic route control policy and a data storage policy for verification by integrally managing with one apparatus.

Description

Network Apparatus Having TAP Function for Collecting Control Signal on the Network for Smart Factory

The present invention relates to a network device that controls network traffic in a network for a smart factory and performs a network tap (TAP) function for copying a process control signal to the incoming network traffic without reducing speed or loss.

In recent years, the manufacturing industry is gradually being advanced, unmanned, and refined through the smart factory business. In particular, finer process control is required for high value-added semiconductor-related production facilities. According to the smart factory, many production equipment such as machine tools put into an unmanned process are built as a single system connected to a server through a network as a client. Servers and production equipment implement a smart factory by exchanging various control signals and processing results through the network.

Various networking errors may occur between the server and the client. For example, the client may not normally receive the control signal provided by the server, and the server may not receive the feedback provided to the server after the client performs an operation according to the control signal. Therefore, the system can control the process normally by verifying the operation of the system while continuously monitoring whether such errors occur. One way to monitor a network is to collect network traffic.

As a method to collect network traffic, you can use the mirroring function of the network equipment. Because mirroring is to copy traffic, depending on the amount of traffic, stability and accuracy problems may occur in the traffic copy due to the load of the network equipment depending on the amount of traffic. have. Or, traffic collection may be fundamentally impossible because the network equipment does not support the mirroring function.

You can use a network tap (TAP) with a function to copy network traffic without using the mirroring function of the network equipment. In this case, a plurality of network TAP equipment and data storage equipment are required. However, if there are restrictions (lack of space, regulation, etc.) on the installation of multiple equipment, installation may not be possible, and difficulties in managing the increased equipment occur.

[Related technical literature]

Republic of Korea Patent Publication No. 10-2016-0002553 (Network Tap)

It is an object of the present invention to provide a network device that controls network traffic in a network for a smart factory and performs a network tap (TAP) function for copying a process control signal to the incoming network traffic without reducing speed or loss.

Considering the various issues mentioned above, it is the most desirable way to collect and store network traffic with a single device. As a specific method, as a physical form, we propose a form that controls network traffic using a network device and performs a network tap (TAP) function that copies the incoming network traffic without reducing speed or loss.

A network device according to the present invention for achieving the above object is connected to a network constituting a smart factory system. The smart factory system has a server and a plurality of production equipment interconnected through a network. The network device of the present invention includes a network connection unit, a tap (TAP) unit, and an internal interface unit.

The network connection unit is connected to the first network to which the management server is connected and constitutes a second network for connecting the plurality of production equipment. The network connection unit switches packets transmitted from the first network to the second network, routes packets transmitted from the second network to the first network, and transmits and receives packets between the first network and the second network. Mirroring with the TAP part. The TAP unit recombines the packets received from the network connection unit according to a preset protocol and transmits them to the monitoring device through the internal interface unit. The internal interface unit is connected to the monitoring device, and provides the packets collected by the tap unit to the monitoring device. The network device of the present invention is connected to the monitoring device through the internal interface unit.

According to an embodiment, the network connection unit, a 10/100 base-TX interface module (Interface Module) 301 for transmitting and receiving Ethernet packets; a differential amplifier (303) for amplifying the packet signal received through the interface module; and a switching chip (IC) that switches the received packet over a LAN and at the same time mirrors the received packet to the tap unit.

According to an embodiment, the network connection unit and the tap (TAP) unit are implemented in the form of a network card (Ethernet Adapter) and mounted on a monitoring device for controlling and monitoring the production equipment.

According to another embodiment, the monitoring device is provided with a data processing unit for classifying and storing the packet provided through the internal interface unit and displaying a control signal from the packet on the display unit for monitoring.

The network device of the present invention can be implemented as a single device in a miniaturized and integrated form, can mirror packets without slowing down or loss of network traffic, and managing traffic path control policies and The data storage policy for verification can be changed and reflected in bulk.

In addition, the network device of the present invention is miniaturized and can be easily attached to production equipment having a PCI-E standard, so that it can be applied to various environments and can quickly respond to device changes or failures.

By using the network device of the present invention, it is possible to monitor network traffic and monitor operation control for production equipment.

1 is a block diagram of a smart factory system having a network device of the present invention;
2 is a diagram showing a network device of the present invention, and
3 is a block diagram of a network connection part of a network device;

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 and 2 , it is a configuration diagram of a smart factory system in which the network device 110 of the present invention is installed. The network device 110 may be connected to a network to route and switch data packets, and collect packets by performing a TAP (Test Access Point) function.

Here, the network includes a first network 10 and a second network 30 . The second network 30 is a local area network (LAN) configured by the network device 110 of the present invention, and the first network 10 is defined as an external network of the second network 30 . Accordingly, the first network 10 may be a wide area network (WAN) or a LAN such as the second network 30 . A management server 50 for controlling the production equipment 71 and 73 may be connected to the first network 10 , and a plurality of production equipments may be connected to the second network 30 . For example, the manager uses the network device 110 to monitor traffic to the production equipment 71 , 73 under the control of the management server 50 , the second network for the production equipment 71 , 73 . (30) can be configured separately. In FIG. 2 , for convenience of explanation, two production equipments 71 and 73 to be monitored are set and described as being connected to the second network 30 .

The management server 50 and production equipment (71, 73) are various servers known in the prior art to constitute a smart factory, and production equipment. The production equipment (71, 73) has a network interface that can connect to the second network (30), can operate according to the control of the management server (50), and transmit a response such as the control result or whether the packet is received or not in a packet is provided to the management server 50 in the form of

The network device 110 configures the second network 30 for production equipment to be monitored and performs a LAN switching operation for the second network 30 . In addition, the network device 110 is connected to the first network 10 to which the management server 50 is connected and performs a routing operation, and routes the packets transmitted by the management server 50 to the production equipment 71 and 73 . .

In addition, the network device 110 is connected to the monitoring device 130 for collecting and monitoring the network traffic transmitted to the production equipment (71, 73) connected to the second network (30). When the network device 110 duplicates a packet and provides it to the monitoring device 130 , the monitoring device 130 classifies, collects, stores, and monitors the network condition.

A method of connecting the network device 110 to the monitoring device 130 may be various. For example, as in FIGS. 1 and 2 , the monitoring device 130 may use a typical desktop computer, and the network device 110 is implemented in the form of a network card (Ethernet Adopter) to monitor a computer in a PCI-E manner. It may be mounted on the device 130 .

Referring to FIG. 1 , a network device 110 includes a network connection unit 210 , a tap (TAP) unit 230 , and an internal interface unit 251 .

The internal interface unit 251 not only electrically connects the network device 110 to the monitoring device 130 , but also transmits and receives data according to a mutually preset protocol under the control of the tab unit 230 . The internal interface unit 251 may use, for example, PCI-E, which is a serial interface interface.

The network connection unit 210 includes a WAN terminal connected to the first network 10 and a plurality of LAN terminals connected to the second network 30 , LAN #1, LAN #2, and LAN #3. . The network connection unit 210 receives a packet routed in the first network 10 through the WAN terminal WAN, and returns the received packet to the first network 10 through the WAN terminal WAN according to the destination path. or switch to the destination via LAN terminals (LAN #1, LAN #2, LAN #3). For example, the management server 50 connected to the first network 10 receives a packet transmitted to the production equipment 71 and 73 and receives a destination through the LAN terminals (LAN #1, LAN #2, LAN #3). It is possible to switch to phosphorus production equipment (71, 73). Conversely, the response sent by the production equipment 71 , 73 belonging to the second network 30 to the management server 50 is also routed back to the first network 10 by the network connection unit 210 .

A method in which the network connection unit 210 is provided with a WAN terminal (WAN) and a LAN terminal (LAN #1, LAN #2, LAN #3) to perform a routing and/or switching operation is various conventionally known routing and/or switching methods. It can be dealt with by applying technology. For example, the network connection unit 210 is a 10/100 base-TX interface module (Interface Module) 301 for transmitting and receiving Ethernet packets as shown in FIG. 2, a differential amplifier for amplifying the received packet signal (Differential Driver) 303 and a switching chip (Switching IC) 305 for switching the received packet may be included.

The network connection unit 210 mirrors all packets switched to the second network 30 (packets delivered to production equipment) and all packets received from the second network 30 (response packets of production equipment) to the tap unit 230 . ) to pass The network connection unit 210 mirrors all packets switching through the LAN terminals (LAN #1, LAN #2, LAN #3). The mirroring method of the network connection unit 210 may use various methods. In the example of FIG. 2 , the switching chip 305 sets the tap unit 230 as one switching port and switches all packets provided to the differential amplifier 303 to a destination (management server or production equipment) and at the same time the tap unit 230 ) can be mirrored.

The tap unit 230 recombines the packet received from the network connection unit 210 according to a topology preset in the internal interface unit 251 in order to deliver it to the monitoring device 130 through the internal interface unit 251 . It is transmitted to the monitoring device 130 .

The monitoring device 130 includes a data processing unit (not shown) that classifies, stores, and manages packets mirrored and transmitted by the network device 110 according to a preset sorting method, and the data processing unit receives a control signal from the collected packets. It may be displayed on a display unit (not shown) for monitoring by an administrator. If necessary, the monitoring device 130 may select, store, and manage specific packets from among the mirrored packets.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

Claims (4)

In a smart factory system having a management server and a plurality of production equipment interconnected through a network, as a network device connected to the network,
The management server is connected to the connected first network and configures a second network for connecting the plurality of production equipment to switch packets transmitted from the first network to the second network, and packets transmitted from the second network a network connection unit for routing to the first network and for mirroring packets transmitted/received between the first network and the second network to a tap unit;
the tap (TAP) unit for recombining the packets received from the network connection unit according to a preset protocol and transferring the packets to the monitoring device through the internal interface unit; and
and the internal interface unit connected to the monitoring device and providing the packets collected by the tap unit to the monitoring device.
According to claim 1,
The network connection unit,
10/100 base-TX interface module (Interface Module) 301 for transmitting and receiving Ethernet packets;
a differential amplifier (303) for amplifying the packet signal received through the interface module; and
and a switching IC for switching the received packet to the tap unit while simultaneously switching the received packet to a LAN.
According to claim 1,
The network connection unit and the tap (TAP) unit is implemented in the form of a network card (Ethernet Adapter) network device, characterized in that mounted on the monitoring device for controlling and monitoring the production equipment.
4. The method of claim 3,
The network device according to claim 1, wherein a data processing unit is installed in the monitoring device to classify and store the packets provided through the internal interface unit and to display a control signal from the packets on a display unit for monitoring.

Images