CN212569488U - Remote automatic power-on control system - Google Patents

Abstract

The utility model discloses a long-range automatic power-on control system, including network switch, a plurality of power chronogenesis ware, power-on control computer, a plurality of radar signal processing computer, a plurality of radar data processing computer, a plurality of radar real time control computer, and the total number of power chronogenesis ware equals the total number of radar signal processing computer, also equals the total number of radar data processing computer, also equals the total number of radar real time control computer. The utility model discloses can realize in a flexible way that the remote automation of semi-physical simulation radar equipment goes up electrical control under different scenes for go up the clean of electrical process, can solve and carry out artifical manual power-on and go up the power-on order easy mistake scheduling problem that exposes to the semi-physical simulation radar equipment of many and complicated.

Description

Remote automatic power-on control system

Technical Field

The utility model relates to a remote automatic power-on control system belongs to power-on control technical field of semi-physical simulation radar equipment.

Background

As the semi-physical simulation radar equipment becomes more complex and more in quantity, the problem that the semi-physical simulation radar equipment is exposed due to manual electrification is more and more, and the safety, the reliability and the stability are difficult to meet the requirements. At present, fewer devices are specially used for electrifying control over the semi-physical simulation radar device, and the devices need to be specially customized and have higher cost.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a remote automatic power-on control system can realize in a flexible way that power-on control is gone up to the remote automation of semi-physical simulation radar equipment under different scenes for go up the electric process succinctly, can solve and carry out artifical manual power-on and go up the power-on order that exposes to the semi-physical simulation radar equipment of many and complicacy and make mistakes scheduling problem easily.

In order to achieve the purpose, the utility model is realized by adopting the following technical scheme:

the utility model provides a remote automatic power-on control system, which comprises a network switch, a plurality of power supply chronographs, a power-on control computer, a plurality of radar signal processing computers, a plurality of radar data processing computers and a plurality of radar real-time control computers, wherein the total number of the power supply chronographs is equal to the total number of the radar signal processing computers, the total number of the radar data processing computers and the total number of the radar real-time control computers;

a signal forwarding end of the network switch is respectively connected with a signal receiving end of each power supply chronograph, a control output end of the power-on control computer, a signal processing network end of each radar signal processing computer, a data processing network end of each radar data processing computer and a real-time control network end of each radar real-time control computer through network cables;

the power supply output end of each power supply time sequence device is respectively connected with the power supply input end of the radar signal processing computer corresponding to the power supply time sequence device, the power supply input end of the radar data processing computer corresponding to the power supply time sequence device and the power supply input end of the radar real-time control computer corresponding to the power supply time sequence device through power supply lines.

Furthermore, the network switch adopts a TP-LINK TL-1024DT 24-port gigabit switch.

Furthermore, the power supply timer adopts a V-90I power supply timer.

Furthermore, the power-on control computer adopts a general Windows 7 computer.

Furthermore, the first radar signal processing computer, the second radar signal processing computer and the third radar signal processing computer are all ADLINK 2U industrial personal computers.

Furthermore, the first radar data processing computer, the second radar data processing computer and the third radar data processing computer are all ADLINK 2U industrial personal computers.

Furthermore, the first radar real-time control computer, the second radar real-time control computer and the third radar real-time control computer are all ADLINK 2U industrial personal computers.

Compared with the prior art, the utility model discloses the beneficial effect who reaches includes at least:

the utility model discloses a method that network switch and power chronograph combined together to the control computer is gone up in the cooperation, can realize in a flexible way that the remote automation of semi-physical simulation radar equipment goes up electrical control under different scenes, makes the electricity process of going up clean, can solve and carry out artifical manual electricity and go up to the semi-physical simulation radar equipment that is in large quantity and complicated and go up the electricity order that exposes and make mistakes scheduling problem easily.

Drawings

Fig. 1 is a block diagram of a remote automatic power-on control system according to an embodiment of the present invention;

fig. 2 is a logic connection diagram of a remote automatic power-on control system provided by an embodiment of the present invention;

fig. 3 is a state monitoring display interface diagram of the remote automatic power-on control system provided by the embodiment of the present invention.

Detailed Description

The present invention will be further described with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.

As shown in fig. 1, an embodiment of the present invention provides a remote automatic power-on control system, which comprises a network switch, a first power sequencer, a second power sequencer, a third power sequencer, a power-on control computer, a first radar signal processing computer, a first radar data processing computer, a first radar real-time control computer, a second radar signal processing computer, a second radar data processing computer, a second radar real-time control computer, a third radar signal processing computer, a third radar data processing computer and a third radar real-time control computer;

the signal transfer end of the network switch is respectively connected with the signal receiving end of the first power supply chronograph, the signal receiving end of the second power supply chronograph, the signal receiving end of the third power supply chronograph, the control output end of the power-on control computer, the signal processing network end of the first radar signal processing computer and the data processing network end of the first radar data processing computer, the real-time control network end of the first radar real-time control computer, the signal processing network end of the second radar signal processing computer, the data processing network end of the second radar data processing computer, the real-time control network end of the second radar real-time control computer, the signal processing network end of the third radar signal processing computer, the data processing network end of the third radar data processing computer and the real-time control network end of the third radar real-time control computer are connected through network cables;

the power supply output end of the first power supply time sequence device is respectively connected with the power supply input end of the first radar signal processing computer, the power supply input end of the first radar data processing computer and the power supply input end of the first radar real-time control computer through power supply lines;

the power supply output end of the second power supply time sequence device is respectively connected with the power supply input end of the second radar signal processing computer, the power supply input end of the second radar data processing computer and the power supply input end of the second radar real-time control computer through power supply lines;

and the power supply output end of the third power supply time sequence device is respectively connected with the power supply input end of the third radar signal processing computer, the power supply input end of the third radar data processing computer and the power supply input end of the third radar real-time control computer through power supply lines.

In this embodiment, the network switch adopts a TP-LINK TL-1024DT 24-port gigabit switch, the power sequencer adopts a security V-90I power sequencer, the power-on control computer adopts a general Windows 7 computer, the first radar signal processing computer, the second radar signal processing computer and the third radar signal processing computer all adopt an ADLINK 2U industrial personal computer, the first radar data processing computer, the second radar data processing computer and the third radar data processing computer all adopt an ADLINK 2U industrial personal computer, and the first radar real-time control computer, the second radar real-time control computer and the third radar real-time control computer all adopt an ADLINK 2U industrial personal computer.

The specific working process of the remote automatic power-on control system is as follows:

as shown in fig. 2, the power-on control software runs on the power-on control computer, the power-on control software forms a logical control connection relationship with the first power source sequencer, the second power source sequencer and the third power source sequencer respectively, and the power-on control software issues control data to the first power source sequencer, the second power source sequencer and the third power source sequencer respectively;

the system comprises a first radar signal processing computer, a first radar data processing computer, a first radar real-time control computer, a second radar signal processing computer, a second radar data processing computer, a second radar real-time control computer, a third radar signal processing computer, a third radar data processing computer and a third radar real-time control computer, wherein the first radar signal processing computer, the second radar real-time control computer, the third radar signal processing computer and the third radar real-time control computer are respectively in logic feedback connection with power-on control software;

the embodiment of the utility model provides an adopt the method that network switch and power chronograph combined together to control computer on the cooperation, through the modification control connection relation logic feedback contact and power-on control software, thereby can realize in a flexible way that the remote automation of semi-physical simulation radar equipment is gone up to electricity under different scenes controls, makes the electricity process of going up succinctly, can solve and carry out artifical manual electricity and go up the electricity sequence that exposes and make mistakes scheduling problem easily to a large amount of and complicated semi-physical simulation radar equipment.

As an embodiment, a state monitoring display interface of the remote automatic power-on control system is shown in fig. 3, where a "radar selection frame" on the interface includes 3 selection frames including "radar 1", "radar 2", and "radar 3", and a semi-physical simulation radar device to be controlled may be selected by a mouse. The power-on control box on the interface comprises 3 buttons of power-on, power-off and quitting, and the power-on function, the power-off function and the software quitting function of the semi-physical simulation radar equipment can be respectively completed by clicking a mouse. The starting state frame on the interface comprises 3 indicating lamps including a radar 1, a radar 2 and a radar 3, and the indicating lamps are respectively used for displaying the starting states of the 3 radars, wherein green indicates that the radars are started, red indicates that the radars are not started, and fig. 3 shows that the radar 1 is started, and the radars 2 and 3 are not started;

the 'key equipment starting state frame' on the interface comprises 9 indicator lamps of 'radar 1 signal processing', 'radar 1 data processing', 'radar 1 real-time control', 'radar 2 signal processing', 'radar 2 data processing', 'radar 2 real-time control', 'radar 3 signal processing', 'radar 3 data processing' and 'radar 3 real-time control', and is respectively used for displaying the starting state of the key equipment of each radar, wherein green represents that the key equipment is started, red represents that the key equipment is not started, and the key equipment of the radar 1 is displayed in figure 3 to be completely started, so that the indicator lamp of the radar 1 is green, the key equipment of the radar 2 is also provided with a real-time control computer to be not started, so that the indicator lamp of the radar 2 is red, the key equipment of the radar 3 is not started, and the indicator lamp of the radar 3 is red;

the embodiment well realizes one-key remote power on and power off operation of the large-quantity and complex semi-physical simulation radar equipment, is convenient and simple, and displays the power on condition of the semi-physical simulation radar equipment through the interface to carry out remote monitoring, so that an operator can clearly master the power on condition of the semi-physical simulation radar equipment.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be considered as the protection scope of the present invention.

Claims (7)

1. A remote automatic power-on control system is characterized by comprising a network switch, a plurality of power supply sequencers, a power-on control computer, a plurality of radar signal processing computers, a plurality of radar data processing computers and a plurality of radar real-time control computers, wherein the total number of the power supply sequencers is equal to the total number of the radar signal processing computers, the total number of the radar data processing computers and the total number of the radar real-time control computers;

a signal forwarding end of the network switch is respectively connected with a signal receiving end of each power supply chronograph, a control output end of the power-on control computer, a signal processing network end of each radar signal processing computer, a data processing network end of each radar data processing computer and a real-time control network end of each radar real-time control computer through network cables;

the power supply output end of each power supply time sequence device is respectively connected with the power supply input end of the radar signal processing computer corresponding to the power supply time sequence device, the power supply input end of the radar data processing computer corresponding to the power supply time sequence device and the power supply input end of the radar real-time control computer corresponding to the power supply time sequence device through power supply lines.

2. The remote automatic power-on control system according to claim 1, wherein the network switch is a TP-LINK TL-1024DT 24-port gigabit switch.

3. The remote automatic power-on control system according to claim 1, wherein the power source sequencer is a safari V-90I power source sequencer.

4. The remote automatic power-on control system as claimed in claim 1, wherein the power-on control computer is a general-purpose Windows 7 computer.

5. The remote automatic power-on control system according to claim 1, wherein the first radar signal processing computer, the second radar signal processing computer and the third radar signal processing computer are all an ADLINK 2U industrial personal computer.

6. The remote automatic power-on control system according to claim 1, wherein the first radar data processing computer, the second radar data processing computer and the third radar data processing computer are all an ADLINK 2U industrial personal computer.

7. The remote automatic power-on control system according to claim 1, wherein the first radar real-time control computer, the second radar real-time control computer and the third radar real-time control computer are all ADLINK 2U industrial personal computers.

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