CN219655853U - Bottle group air supply system for intelligent micro-pipe network ecological chain - Google Patents

Abstract

The utility model relates to a bottle group air supply system for an intelligent microtube network ecological chain, which comprises a main bottle group busbar pipeline assembly, wherein the main bottle group busbar pipeline assembly comprises more than one main fuel bottle communicated with a first busbar; the bottle group pressure regulating assembly comprises a first high-pressure regulator arranged on the first bus-bar pipe and a low-pressure regulator arranged on the second bus-bar pipe; the bottle group data acquisition assembly comprises a data acquisition terminal for acquiring data and a data monitoring group for monitoring the data; the first bus bar is communicated with the second bus bar, and the second bus bar is connected with an air terminal; the data monitoring group is arranged on the first bus bar and/or the second bus bar. The bottle group air supply system can effectively improve the existing air supply mode and improve the safety.

Description

Bottle group air supply system for intelligent micro-pipe network ecological chain

Technical Field

The utility model relates to an air supply system, in particular to a bottle group air supply system for an intelligent micro-pipe network ecological chain.

Background

The opinion of the central national institute about the key work of comprehensively promoting the county in 2023 years "promotes the urban and rural overall construction and management and protection of common service facilities such as county power supply, air supply, telecommunication, postal service and the like, and the conditional areas promote the extension of the municipal pipe network, the rural micro-pipe network and the like to the households" the central first file promotes the rural micro-pipe network project again, so as to improve the current situation of each household of a single rural gas cylinder; because the current situation that each gas bottle enters each household can cause that the background is difficult to uniformly monitor the gas supply condition of each gas bottle of each household, when abnormality occurs, the background cannot monitor at the first time and take measures to reduce the safety accident of the gas bottle; therefore, the current situation of single bottle gas consumption needs to be improved, and the life and property safety of people is protected.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art, and provides a bottle group air supply system for an intelligent micro-pipe network ecological chain, which can effectively improve the existing air supply mode and improve the safety.

The purpose of the utility model is realized in the following way:

a bottle group air supply system for an intelligent micro-pipe network ecological chain comprises,

a main bottle group busway pipe assembly comprising more than one main fuel bottle communicating with a first busway pipe;

the bottle group pressure regulating assembly comprises a first high-pressure regulator arranged on the first bus-bar pipe and a low-pressure regulator arranged on the second bus-bar pipe;

the bottle group data acquisition assembly comprises a data acquisition terminal for acquiring data and a data monitoring group for monitoring the data;

the first bus bar is communicated with the second bus bar, and the second bus bar is connected with an air terminal; the data monitoring group is arranged on the first bus bar and/or the second bus bar.

As a specific scheme, the data monitoring group comprises a first pressure collector arranged on the first bus-bar and a second pressure collector arranged on the second bus-bar; the data acquisition terminal is in data connection with the first pressure collector and the second pressure collector so as to acquire pressure data on the first bus-bar and the second bus-bar.

As a further specific scheme, the data monitoring group further comprises a gas leakage alarm for collecting the concentration of the surrounding gas-phase fuel; and the data acquisition terminal is in data connection with the gas leakage alarm to detect whether the surrounding environment has gas-phase fuel leakage.

As still another specific scheme, the bottle group data acquisition assembly further comprises an electromagnetic cut-off valve arranged on the second busbar, and the data acquisition terminal is in control connection with the electromagnetic cut-off valve so as to control the on-off of the second busbar.

As a further specific scheme, the data acquisition terminal is in communication connection with a cloud server, and the cloud server is in communication connection with the management terminal.

As yet another specific aspect, the master cylinder manifold assembly further includes a first relief valve disposed on the first manifold.

As still another specific scheme, the second busbar is communicated with a sewage outlet.

As still another specific scheme, the bottle group air supply system further comprises a bottle group metering assembly, the bottle group metering assembly comprises a mass flowmeter arranged on a third confluence pipe, and the second confluence pipe is communicated with the air utilization terminal through the third confluence pipe.

As a further specific scheme, the bottle group air supply system further comprises a secondary bottle group busbar pipeline assembly, wherein the secondary bottle group busbar pipeline assembly comprises more than one secondary fuel bottle communicated with a fourth busbar; the fourth bus bar is communicated with the second bus bar; the bottle group pressure regulating assembly further comprises a second high-pressure regulator arranged on the fourth bus tube.

As yet another specific scheme, the first high pressure regulator outlet pressure set point P1 is greater than the second high pressure regulator outlet pressure set point P2, where P1 is 0.14MPa and P2 is 0.12MPa.

The beneficial effects of the utility model are as follows:

the bottle group gas supply system can be used for quadruple self-protection such as gas supply informatization monitoring, electric control, mechanical self-protection, safety pre-warning and the like of liquefied petroleum gas, can remotely transmit monitored data to a cloud server in real time, realizes accurate and unified interlocking control of parameters such as high pressure, low pressure, gas leakage and the like of a fuel bottle group, and has the advantages of integrated and associated development of all parts in the system, reasonable structure and complete functions; the remote data sensor is adopted in the bottle group air supply system to collect pressure and leakage alarm data, and the electromagnetic cut-off valve of the pipeline is controlled through the operation of the single chip microcomputer, so that the pipeline control is realized, and the intelligent network operation is realized for the cloud server. The bottle group air supply system can effectively improve the existing air supply mode and improve the safety.

Drawings

FIG. 1 is a process flow diagram of a bottle group air supply system in accordance with one embodiment of the present utility model.

Fig. 2 is a schematic diagram of a bottle group air supply system according to an embodiment of the present utility model.

Detailed Description

The utility model is further described below with reference to the drawings and examples.

Referring to fig. 1 and 2, the present embodiment relates to a bottle group air supply system, comprising,

a main bottle group confluence pipe assembly 100, wherein the main bottle group confluence pipe assembly 100 comprises more than one main fuel bottle 1 communicated with a first confluence pipe 4, and four main fuel bottles 1 are arranged in the embodiment; the main bottle group confluence pipe assembly 100 can effectively collect liquid phase fuel (liquefied petroleum gas) in each main fuel bottle 1;

a sub-bottle group confluence pipe assembly 500, the sub-bottle group confluence pipe assembly 500 including more than one sub-fuel bottle 21 communicating with a fourth confluence pipe 24, the sub-fuel bottles 21 being provided with four in this embodiment;

the bottle group pressure regulating assembly 200, the bottle group pressure regulating assembly 200 comprises a first high-pressure regulator 8 arranged on the first bus-bar pipe 4, a low-pressure regulator 11 arranged on the second bus-bar pipe 12, and a second high-pressure regulator 28 arranged on the fourth bus-bar pipe 24; the bottle group pressure regulating assembly 200 is divided into two stages of pressure regulation, wherein the first stage of pressure regulation is that a first high-pressure regulator 8 regulates the high pressure (0.01-1.56 MPa) in a first busbar 4 to the medium pressure (0.01-0.2 MPa), a second high-pressure regulator 28 regulates the high pressure (0.01-1.56 MPa) in a fourth busbar 24 to the medium pressure (0.01-0.2 MPa), and the second stage of pressure regulation is that a low-pressure regulator 11 regulates the medium pressure in a second busbar 12 to the low pressure (4 kPa) and is used by a user after metering; the first high-pressure regulator 8 and the second high-pressure regulator 28 respectively monitor the pressure of the pipeline in real time and upload the pressure to the cloud server so as to monitor the operation condition of the bottle group air supply system, for example, the first bus-bar pipe 4 or the second high-pressure regulator 28 has low pressure (the system set monitoring pressure is 0.12 MPa), the system defaults that the liquid phase fuel in the main fuel bottle 1 or the auxiliary fuel bottle 21 is used up, and the system monitoring can give an alarm and upload the alarm to the cloud server so as to remind an operation unit to replace the corresponding bottle group in time.

The bottle group data acquisition assembly 300, the bottle group data acquisition assembly 300 comprises a data acquisition terminal 31 for acquiring data and a data monitoring group for monitoring data; the bottle group data acquisition component 300 acquires data such as pressure, gas leakage alarm, video monitoring and the like through the data acquisition terminal 31, and controls the pipeline electromagnetic cut-off valve through the single chip microcomputer operation to realize pipeline control and realize intelligent network operation to the cloud server;

the first bus bar 4 is communicated with the second bus bar 12, and the second bus bar 12 is connected with the air terminal A; the fourth bus bar 24 communicates with the second bus bar 12; the data monitoring group is disposed on the first bus bar 4 and the second bus bar 12.

Further, the data monitoring group includes a first pressure collector 7 disposed on the first bus bar 4, a second pressure collector 13 disposed on the second bus bar 12, and a third pressure collector 26 disposed on the fourth bus bar 24; the data collection terminal 31 data-connects the first, second and third pressure collectors 7, 13 and 26 to collect pressure data on the first, second and fourth bus bars 4, 12 and 24. The first pressure collector 7 is connected with a first high-pressure mechanical pressure gauge 6 so as to display pressure data monitored by the first pressure collector 7; the second pressure collector 13 is connected with a low-pressure mechanical pressure gauge 14 to display pressure data monitored by the second pressure collector 13; a second high pressure mechanical pressure gauge 27 is connected to the third pressure collector 26 to display pressure data monitored by the third pressure collector 26.

Further, the data monitoring group also includes a gas leak alarm 29 for collecting the ambient gas phase fuel concentration; the data acquisition terminal 31 is in data connection with the gas leakage alarm 29 to detect whether the surrounding environment has gas-phase fuel leakage; the gas leakage alarm 29 has an audible and visual alarm function.

Further, the bottle group data acquisition assembly 300 further comprises an electromagnetic cut-off valve 10 arranged on the second busbar 12, and the data acquisition terminal 31 is controlled to be connected with the electromagnetic cut-off valve 10 so as to control the on-off of the second busbar 12; the electromagnetic cut-off valve 10 has a function of cutting off the pipeline under emergency under electric control. The gas-phase fuel subjected to pressure regulation by the first high-pressure regulator 8 enters the low-pressure regulator 11 through the electromagnetic cut-off valve 10; when an emergency occurs in the bottle group air supply system, the electromagnetic cut-off valve 10 automatically cuts off the second confluence pipe 12; emergency situations include gas phase fuel leakage, monitoring for fire, first safety valve 5 or second safety valve 25 being opened, mass flowmeter 17 outlet flow being excessive, etc.; when the gas-phase fuel leakage is detected, the gas leakage alarm 29 gives an audible and visual alarm, and closes the electromagnetic cut-off valve 10, thereby playing a role in safety protection.

Further, the data collection terminal 31 is communicatively connected to a cloud server, and the cloud server is communicatively connected to a management terminal, where the management terminal may be a smart phone, a computer, etc. controlled by an administrator.

Further, the main bottle group confluence pipe assembly 100 further includes a first safety valve 5 provided on the first confluence pipe 4; the sub-bottle group manifold assembly 500 further includes a second relief valve 25 provided on the fourth manifold 24; the safety pressure set by the first safety valve 5 and the second safety valve 25 was 2.28MPa.

Further, the second busbar 12 is communicated with a drain outlet 19, and the drain outlet 19 is provided with a drain ball valve 20, so that the waste is discharged and the residue is treated during system maintenance.

Further, the bottle group air supply system further comprises a bottle group metering assembly 400, wherein the bottle group metering assembly 400 comprises a mass flowmeter 17 arranged on a third bus bar 18, and the second bus bar 12 is connected with an air terminal A through the third bus bar 18; the bottle group metering component 400 can meter the user gas consumption data in real time and upload the cloud server to realize intelligent network operation. The inlet pressure of the low-pressure regulator 11 is set to be 0.01-0.2 MPa, the outlet pressure is set to be 3.8kPa, the closing pressure is smaller than 4.6kPa, and the gas-phase fuel regulated by the low-pressure regulator 11 is metered by the mass flowmeter 17 and is used by the gas terminal A. The second pressure collector 13 can effectively monitor the outlet pressure of the low-pressure regulator 11, when the monitored pressure is less than 2kpa, the system alarms again, the cloud server is uploaded, and meanwhile, the electromagnetic cut-off valve 10 is closed, and the system is shut down.

Further, the outlet pressure set point P1 of the first high pressure regulator 8 is greater than the outlet pressure set point P2 of the second high pressure regulator 28, where P1 is 0.14MPa and P2 is 0.12MPa. The first high-pressure regulator 8 and the second high-pressure regulator 28 can respectively regulate the pressure of the high-pressure gas-phase fuel to the medium-pressure gas-phase fuel, and the medium-pressure gas-phase fuel after the high-pressure regulation enters a low-pressure regulating system to carry out secondary pressure regulation. The first high-voltage regulator 8 and the second high-voltage regulator 28 are respectively set with different outlet pressures, when the outlet pressure of the first high-voltage regulator 8 is larger than that of the second high-voltage regulator 28, the first high-voltage regulator 8 can effectively prevent backflow, at the moment, the second high-voltage regulator 28 is automatically closed, the first high-voltage regulator 8 automatically operates, and the function belongs to the mechanical performance of the voltage regulators (the first high-voltage regulator 8 and the second high-voltage regulator 28); when the outlet pressure of the second high-pressure voltage regulator 28 is greater than the outlet pressure of the first high-pressure voltage regulator 8, the first high-pressure voltage regulator 8 is automatically closed, the pressure in the first bus-bar pipe 4 is reduced, the pressure in the fourth bus-bar pipe 24 is in a normal range, at the moment, the system can alarm again to upload the cloud server to remind an operation unit to replace the main fuel bottle 1, the operation mode can effectively ensure the gas consumption of a user, automatic operation is realized, the operation cost of the operation unit is reduced, and the gas inspection feeling of the user is improved.

Further, each main fuel bottle 1 is communicated with a first busbar 4 through a corresponding first high-pressure rubber tube 2, a first high-pressure ball valve 3 is arranged on the first high-pressure rubber tube 2, and the first high-pressure ball valve 3 is used for cutting off or replacing the main fuel bottle 1 in an emergency; each auxiliary fuel bottle 21 is communicated with a fourth bus-bar pipe 24 through a corresponding second high-pressure rubber pipe 22, a second high-pressure ball valve 23 is arranged on the second high-pressure rubber pipe 22, and the second high-pressure ball valve 23 is used for cutting off or replacing the auxiliary fuel bottle 21 in an emergency.

The foregoing is a preferred embodiment of the utility model showing and describing the general principles, features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing description merely illustrates the principles of the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. A bottle group air feed system for intelligent micro-pipe network ecological chain, its characterized in that: comprising the steps of (a) a step of,

a main bottle group bus duct assembly (100), the main bottle group bus duct assembly (100) comprising more than one main fuel bottle (1) communicating with a first bus duct (4);

the bottle group pressure regulating assembly (200), the bottle group pressure regulating assembly (200) comprises a first high-pressure regulator (8) arranged on a first bus-bar pipe (4) and a low-pressure regulator (11) arranged on a second bus-bar pipe (12);

a bottle group data acquisition assembly (300), the bottle group data acquisition assembly (300) comprising a data acquisition terminal (31) for acquiring data, and a data monitoring group for monitoring data;

the first bus pipe (4) is communicated with the second bus pipe (12), and the second bus pipe (12) is communicated with an air terminal (A); the data monitoring group is arranged on the first bus bar (4) and/or the second bus bar (12).

2. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to claim 1, wherein: the data monitoring group comprises a first pressure collector (7) arranged on the first bus-bar (4) and a second pressure collector (13) arranged on the second bus-bar (12); the data acquisition terminal (31) is in data connection with the first pressure collector (7) and the second pressure collector (13) so as to acquire pressure data on the first bus-bar (4) and the second bus-bar (12).

3. The bottle group air supply system for an intelligent microtubule network ecological chain of claim 2, wherein: the data monitoring group further comprises a gas leakage alarm (29) for collecting the concentration of the surrounding gas phase fuel; the data acquisition terminal (31) is in data connection with the gas leakage alarm (29) so as to detect whether the surrounding environment has gas-phase fuel leakage.

4. The bottle group air supply system for an intelligent microtubule network ecological chain of claim 2, wherein: the bottle group data acquisition assembly (300) further comprises an electromagnetic cut-off valve (10) arranged on the second busbar tube (12), and the data acquisition terminal (31) is in control connection with the electromagnetic cut-off valve (10) so as to control the on-off of the second busbar tube (12).

5. The bottle group air supply system for an intelligent microtubule network ecological chain of claim 2, wherein: the data acquisition terminal (31) is in communication connection with a cloud server, and the cloud server is in communication connection with the management terminal.

6. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to claim 1, wherein: the main bottle group confluence pipe assembly (100) further comprises a first safety valve (5) arranged on the first confluence pipe (4).

7. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to claim 1, wherein: the second bus pipe (12) is communicated with a sewage outlet (19).

8. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to claim 1, wherein: the bottle group air supply system further comprises a bottle group metering assembly (400), the bottle group metering assembly (400) comprises a mass flowmeter (17) arranged on a third bus-bar (18), and the second bus-bar (12) is communicated with the air utilization terminal (A) through the third bus-bar (18).

9. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to any one of claims 1 to 8, wherein: the bottle group air supply system further comprises a secondary bottle group bus pipe assembly (500), wherein the secondary bottle group bus pipe assembly (500) comprises more than one secondary fuel bottle (21) communicated with a fourth bus pipe (24); the fourth bus bar (24) is communicated with the second bus bar (12); the bottle group pressure regulating assembly (200) further comprises a second high-pressure regulator (28) arranged on the fourth bus-bar pipe (24).

10. The bottle group air supply system for an intelligent micro-pipe network ecological chain according to claim 9, wherein: the outlet pressure set point P1 of the first high-pressure regulator (8) is larger than the outlet pressure set point P2 of the second high-pressure regulator (28).