CN215114664U - Building secondary water supply monitoring system - Google Patents

Abstract

The utility model discloses a building secondary water supply monitoring system, include the data acquisition terminal that carries out the collection to each data of secondary water supply, carry out the data processor who handles and carry out remote communication's remote control terminal with data processor to the data that data acquisition terminal obtained, data processor includes and carries out the signal adjustment unit that pairs one by one with data acquisition terminal's signal to the signal of receiving and remote control terminal, carries out the signal conversion unit that changes with the signal in the signal adjustment unit, with the signal transmission unit of signal conversion unit output to remote control terminal. The utility model discloses can unify each data acquisition terminal and show on remote control terminal to improve the nature directly perceived of surveing, avoid makeing mistakes, but wide application in secondary water supply monitoring field.

Description

Building secondary water supply monitoring system

Technical Field

The utility model belongs to the technical field of urban water supply management technique and specifically relates to a building secondary water supply monitoring system is related to.

Background

In high-rise dwellings, tap water needs to be supplied by a secondary water supply to ensure sufficient pressure. In actual use, in order to ensure normal use of secondary water supply, the water pressure and the water storage capacity of the secondary water supply and the operation conditions of all devices need to be monitored. After the parameters are collected by the data collection equipment, the parameters are transmitted to the remote control platform. The data transmission mode adopted by the manufacturer A is modbusRTU, the internal data code 40001 represents the water level of a water tank, 40002 represents the water inlet pressure, 40003 represents the water outlet pressure, 40004 represents the accumulated flow, 40005 represents the instantaneous flow, the data transmission mode adopted by the manufacturer B is ModbusTCP/IP, wherein the internal data code 40001 represents the water outlet pressure, 40002 represents the water inlet pressure, 40003 represents the water level of the water tank, 40004 represents the instantaneous flow, 40005 represents the accumulated flow, and the manufacturers form a set of respective standards uniformly according to the programming habits of the manufacturers and cannot form a uniform rule in a secondary water supply pipeline. Therefore, in the existing monitoring system, each secondary water supply device is correspondingly provided with a data sending device, the data sending device directly transmits the data acquired by the data acquisition device to the remote control platform, and the remote control platform receives and checks the data. Because the signals adopted by the devices are different and the acquisition contents represented by the codes are different, as described above, the monitoring contents corresponding to the codes 40001, 40002, 40003, 40004 and 40005 are different, so that the service personnel is required to perform pairing reading according to different manufacturer data, the observation is troublesome, and the operators unfamiliar with the service can also be misseen to influence the normal water supply scheduling.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a building secondary water supply monitoring system solves the problem that current detecting system surveys the trouble and easily makes mistakes.

The utility model provides a technical scheme that its technical problem adopted is: the utility model provides a building secondary water supply monitoring system, includes the data acquisition terminal that carries out the collection to each data of secondary water supply, carries out the data processor who handles and carry out remote communication's remote control terminal with data processor to the data that data acquisition terminal obtained, data processor includes and carries out the signal adjustment unit that pairs one by one with data acquisition terminal's signal to the signal of receiving and remote control terminal's signal, carries out the signal conversion unit that the signal in the signal adjustment unit changes, with the signal transmission unit of signal conversion unit output to remote control terminal.

Furthermore, an RS485 interface, an RJ45 interface or an RS232 interface is adopted between the data acquisition terminal and the data receiving unit for signal transmission.

Preferably, the signal transmission unit and the remote control terminal perform signal transmission by using a UDP protocol.

The utility model has the advantages that: the utility model discloses a data processor's design, the signal that sends a plurality of data acquisition terminals carries out signal conversion and pairs with remote control terminal's code to the convenience directly reads on remote control terminal, because the monitoring content that every each code represented on remote terminal is unanimous, consequently, can form the mode of data list, make things convenient for the holistic observation of system, can also carry out contrastive analysis, in time discover unusual data and in time make corresponding processing.

The present invention will be described in more detail with reference to the accompanying drawings and examples.

Drawings

Fig. 1 is a system block diagram of the present invention.

Detailed Description

In an embodiment, as shown in fig. 1, a building secondary water supply monitoring system includes a set of data acquisition terminals 1 for acquiring data of secondary water supply, a data processor 2 for processing the data acquired by the data acquisition terminals 1, and a remote control terminal 3 for performing remote communication with the data processor 2.

The data acquisition terminal 1 is generally configured with one set of 1 secondary water supply device, and is used for collecting signals of each sensor in the secondary water supply device and carrying out arrangement transmission according to numbers. For example, the number 40001 represents the water level of the water tank, 40002 represents the water inlet pressure, 40003 represents the water outlet pressure, 40004 represents the cumulative flow rate, 40005 represents the instantaneous flow rate … …

The data processor 2 comprises a group of data receiving units 21 which are in butt joint with the data acquisition terminal 1, signal adjusting units 22 which are used for performing one-to-one matching on received signals and signals of the remote control terminal 3, a signal converting unit 23 which is used for converting the signals in the signal adjusting units 22, and a signal sending unit 24 which is used for sending the signals output by the signal converting unit 23 to the remote control terminal 3. The data acquisition terminal 1 and the data receiving unit 21 may adopt interfaces such as RS485, RS232, RJ45, etc. to perform signal transmission. Preferably, the signal sending unit 24 and the remote control terminal 3 use a UDP protocol for signal transmission, and an interface uses RS 485. The signal adjusting unit 22 compares and adjusts the number in the data acquisition terminal 1 with the number corresponding to the remote control terminal 3, and if the original number 40001 in the data acquisition terminal 1 represents the water level of the water tank, and the number of the water level of the water tank in the remote control terminal 3 is 40002, the signal adjusting unit 22 adjusts the number 40001 in the data acquisition terminal 1 to 40002, so as to ensure consistency with the remote control terminal 3.

The remote control terminal 3 is internally provided with a monitoring list, so that the overall observation of the system is facilitated, the comparison and analysis can be carried out, abnormal data can be found in time, and corresponding processing can be carried out in time.

The invention has been described above by way of example with reference to the accompanying drawings. Obviously, the specific implementation of the present invention is not limited by the above-described manner. Various insubstantial improvements are made by adopting the method conception and the technical proposal of the utility model; or without improvement, the above conception and technical solution of the present invention can be directly applied to other occasions, all within the protection scope of the present invention.

Claims (3)

1. The utility model provides a building secondary water supply monitoring system, includes data acquisition terminal (1) that each data of secondary water supply carried out the collection, carries out data processor (2) that handle and remote control terminal (3) that carry out remote communication with data processor (2) to the data that data acquisition terminal (1) obtained, its characterized in that: the data processor (2) comprises a group of data receiving units (21) which are in butt joint with the data acquisition terminal (1), signal adjusting units (22) which are used for performing one-to-one pairing on received signals and signals of the remote control terminal (3), a signal converting unit (23) which is used for converting the signals in the signal adjusting units (22), and a signal sending unit (24) which is used for sending the signals output by the signal converting unit (23) to the remote control terminal (3).

2. The building secondary water supply monitoring system of claim 1, wherein: and an RS485 interface, an RS232 interface or an RJ45 interface is adopted between the data acquisition terminal (1) and the data receiving unit (21) for signal transmission.

3. The building secondary water supply monitoring system of claim 1, wherein: and the signal sending unit (24) and the remote control terminal (3) adopt a UDP protocol for signal transmission.

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