CN220852307U - Remote monitoring feedback control system for heating - Google Patents

Abstract

The utility model provides a remote monitoring feedback control system for heating, which comprises an installation box, a water inlet pipeline, a water outlet pipeline and a matched controller. The water inlet pipeline is arranged in the mounting box, two ends of the water inlet pipeline extend out of the mounting box respectively, one end of the water inlet pipeline can be communicated with a water inlet pipe for heating, and the other end of the water inlet pipeline is communicated with a heating pipeline for heating users. The water inlet pipe is respectively provided with a first electromagnetic valve, a first filter, a first thermometer and a first flowmeter. The water outlet pipeline is arranged in the mounting box, two ends of the water outlet pipeline extend out of the mounting box respectively, one end of the water outlet pipeline can be communicated with a water return pipe for heating, and the other end of the water outlet pipeline is communicated with a heating pipeline for heating users. The water outlet pipeline is respectively provided with a second electromagnetic valve and a second thermometer second flowmeter. The remote monitoring feedback control system for heating provided by the utility model can monitor the heating condition of a heating user in real time, and has strong practicability.

Description

Remote monitoring feedback control system for heating

Technical Field

The utility model belongs to the technical field of intelligent heating monitoring, and particularly relates to a remote monitoring feedback control system for heating.

Background

Heating is to supply heat to a building to keep a certain indoor temperature, and is a social service for solving the basic life requirement of heating in winter. With the construction of towns, central heating is more and more widespread, and is a clean and guaranteed heating mode in which a heating company transmits heat to a user's home through a pipeline, and the mode is low in price and relatively high in safety performance.

In the prior art, because the area corresponding to central heating is wider, the management of each heating user has great disadvantages. The following is common: 1. the pipeline is blocked, so that the flow of hot water is reduced, the heating temperature cannot be guaranteed, the condition cannot be monitored in real time, and the condition cannot be treated in time; 2. when a heating user steals water, the water cannot be monitored in real time, so that water is wasted; 3. the heating temperature of a heating user cannot be timely fed back; 4. after the heating user pays fees, the heating pipeline of the heating user is opened after the water inlet pipe and the water return pipe are opened at the pipeline well by manpower. Therefore, in the process of central heating, a terminal capable of feeding back and controlling the heating situation in time is needed to solve the above-mentioned problems.

Disclosure of utility model

The embodiment of the utility model provides a remote monitoring feedback control system for heating, which aims to realize the purpose of monitoring and controlling the heating condition of a heating user in real time.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the remote monitoring feedback control system for heating comprises an installation box, a water inlet pipeline, a water outlet pipeline and a matched controller; the water inlet pipeline is arranged in the installation box, two ends of the water inlet pipeline extend out of the installation box respectively, one end of the water inlet pipeline is used for being communicated with a water inlet pipe for heating, and the other end of the water inlet pipeline is communicated with a heating pipeline for a heating user; the water inlet pipe is internally provided with a first electromagnetic valve, a first filter, a first thermometer and a first flowmeter respectively; the water outlet pipeline is arranged in the installation box, two ends of the water outlet pipeline extend out of the installation box respectively, one end of the water outlet pipeline is used for being communicated with a water return pipe for heating, and the other end of the water outlet pipeline is communicated with a heating pipeline for heating users; and the water outlet pipeline is respectively provided with a second electromagnetic valve and a second thermometer second flowmeter.

In one possible implementation manner, two first electromagnetic valves are provided, and the two first electromagnetic valves are arranged at intervals; the first filter is positioned between the two first electromagnetic valves.

In one possible implementation manner, the remote monitoring feedback control system for heating further comprises a back flushing structure, wherein the back flushing structure comprises a third electromagnetic valve, an intermediate pipeline, a second filter, a fourth electromagnetic valve and a circulating pump; the third electromagnetic valve is arranged on the water outlet pipeline and is arranged at intervals with the second electromagnetic valve; the two intermediate pipelines are arranged, the two intermediate pipelines are positioned between the two first electromagnetic valves, the two intermediate pipelines are positioned between the second electromagnetic valve and the third electromagnetic valve, and the two ends of each intermediate pipeline are respectively communicated with the water inlet pipeline and the water outlet pipeline; the second filter is arranged on the water outlet pipeline and is positioned between the two middle pipelines; the two fourth electromagnetic valves are arranged on the two middle pipelines respectively; the circulating pump is arranged on one of the intermediate pipelines.

In one possible implementation, the first filter is located between two intermediate lines.

In one possible implementation manner, each of the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, and each of the fourth electromagnetic valve are electrically connected with the controller.

In one possible implementation, the first thermometer and the second thermometer are each electrically connected to the controller.

In one possible implementation, the first flow meter and the second flow meter are both electrically connected to the controller.

In this implementation mode, the hot water in the inlet tube can be guaranteed to the delivery to heating user to the inlet tube, and the outlet pipe way can be guaranteed to flow through in the hot water backward flow to the wet return of heating user, and then guarantees the heat supply work. And the first filter can ensure that the hot water is filtered so as to prevent impurities and the like in the hot water from entering a heating user. The first electromagnetic valve and the second electromagnetic valve can be opened and closed under the control of the controller, so that the control of heating user heat supply work is ensured, and the labor is saved. The first flowmeter and the second flowmeter can monitor the hot water quantity entering and exiting the heating user in real time, so that the condition that the heating user steals water or a pipeline is blocked and the like can be judged conveniently, and meanwhile, a heating power company can conveniently control heat supply through the first electromagnetic valve and the second electromagnetic valve. The first thermometer and the second thermometer can monitor the water inlet and outlet temperatures of the heating user, so that the indoor temperature of the heating user is judged to be monitored.

Drawings

Fig. 1 is a schematic structural diagram of a remote monitoring feedback control system for heating according to an embodiment of the present utility model;

Fig. 2 is a schematic diagram of a front view structure of a remote monitoring feedback control system for heating according to an embodiment of the present utility model;

reference numerals illustrate:

10. A mounting box; 20. a water inlet pipeline; 21. a first electromagnetic valve; 22. a first filter; 23. a first thermometer; 24. a first flowmeter; 30. a water outlet pipeline; 31. a second electromagnetic valve; 32. a second thermometer; 33. a second flowmeter; 40. a back flushing structure; 41. a third electromagnetic valve; 42. an intermediate pipeline; 43. a second filter; 44. a fourth electromagnetic valve; 45. and a circulation pump.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 and 2 together, a description will be given of a remote monitoring feedback control system for heating according to the present utility model. The remote monitoring feedback control system for heating comprises a mounting box 10, a water inlet pipeline 20, a water outlet pipeline 30 and a matched controller. The water inlet pipeline 20 is arranged in the installation box 10, two ends of the water inlet pipeline 20 extend out of the installation box 10 respectively, one end of the water inlet pipeline 20 can be communicated with a water inlet pipe for heating, and the other end of the water inlet pipeline is communicated with a heating pipeline for a heating user. The water inlet pipe is provided with a first solenoid valve 21, a first filter 22, a first thermometer 23 and a first flowmeter 24, respectively. The water outlet pipeline 30 is arranged in the installation box 10, two ends of the water outlet pipeline 30 extend out of the installation box 10 respectively, one end of the water outlet pipeline 30 can be communicated with a water return pipe for heating, and the other end of the water outlet pipeline is communicated with a heating pipeline for a heating user. The water outlet pipeline 30 is provided with a second electromagnetic valve 31 and a second thermometer 32 and a second flowmeter 33 respectively.

The remote monitoring feedback control system for heating that this embodiment provided, the control principle is: when the values of the first flow meter 24 and the second flow meter 33 are identical and are lower than the normal values, it is determined that the pipe (the first filter 22) is clogged; when the value of the first flowmeter 24 is greater than the value of the second flowmeter 33, it can be determined that the heating user steals water at this time; the value of the first thermometer 23 remains substantially unchanged, and when the difference between the first thermometer 23 and the second thermometer 32 becomes large, it is indicated that the external ambient temperature is reduced; in addition, the opening of the heating may be controlled directly by the controller for the first solenoid valve 21 and the second solenoid valve 31.

Compared with the prior art, the remote monitoring feedback control system for heating provided by the embodiment can ensure that hot water in the water inlet pipe is transferred to a heating user, and the water outlet pipeline 30 can ensure that hot water flowing through the heating user flows back into the water return pipe, so that heat supply work is ensured. And the first filter 22 can ensure filtering of the hot water to prevent foreign substances and the like in the hot water from entering into the heating user. The first electromagnetic valve 21 and the second electromagnetic valve 31 can be opened and closed under the control of the controller, so that the control of the heating user for heating work is ensured, and the labor is saved. The first flowmeter 24 and the second flowmeter 33 can monitor the hot water quantity entering and exiting the heating user in real time, so that the condition of water theft or pipeline blockage and the like of the heating user can be conveniently judged, and meanwhile, a heating company can conveniently control the heat supply through the first electromagnetic valve 21 and the second electromagnetic valve 31. The first thermometer 23 and the second thermometer 32 can ensure that the temperature of water entering and exiting from a heating user is monitored, so that the indoor temperature of the heating user is judged to be monitored.

It should be noted that, the controller may include a controller and a remote display control unit, which are electrically connected to each other, so as to ensure remote monitoring and remote control of the thermal company.

In addition, the remote monitoring feedback control system for heating provided by the embodiment of the utility model can be arranged in a piping shaft, so that illegal operation of heating users is avoided.

In some embodiments, the first electromagnetic valve 21 may have a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, two first solenoid valves 21 are provided, and the two first solenoid valves 21 are disposed at intervals. The first filter 22 is located between the two first solenoid valves 21.

This structure can ensure that after the first filter 22 is blocked, the two first electromagnetic valves 21 can be closed at the same time, so that the first filter 22 is cleaned by a worker.

In some embodiments, referring to fig. 1 and 2, the heating remote monitoring feedback control system further includes a back flushing structure 40, the back flushing structure 40 including a third solenoid valve 41, an intermediate line 42, a second filter 43, a fourth solenoid valve 44, and a circulation pump 45. The third solenoid valve 41 is provided on the water outlet line 30 and is spaced apart from the second solenoid valve 31. The two intermediate pipelines 42 are arranged, the two intermediate pipelines 42 are located between the two first electromagnetic valves 21, the two intermediate pipelines 42 are located between the second electromagnetic valve 31 and the third electromagnetic valve 41, and two ends of each intermediate pipeline 42 are respectively communicated with the water inlet pipeline 20 and the water outlet pipeline 30. A second filter 43 is arranged on the outlet conduit 30 between the two intermediate conduits 42. The fourth solenoid valves 44 are provided in two, and the two fourth solenoid valves 44 are provided in the two intermediate pipes 42, respectively. A circulation pump 45 is provided on one of the intermediate pipes 42.

Through back flush structure 40, can shift the impurity in the first filter 22 to in the second filter 43, and then along with the normal operating back of heat supply work, make the impurity in the second filter 43 directly carry by the water in outlet pipeline 30 and get into the wet return, can effectually reduce staff's intensity of labour, avoid heating user's latency overlength, its simple structure, the practicality is strong.

In this embodiment, the specific workflow for backwash structure 40 is; when the flow rate of the first flow meter 24 and the flow rate of the second flow meter 33 are both reduced, the controller controls the two first solenoid valves 21 to be closed simultaneously, and the second solenoid valve 31 and the third solenoid valve 41 to be closed; the two fourth electromagnetic valves 44 are opened, at this time, the two intermediate pipelines 42, the water inlet pipeline 20 and the water outlet pipeline 30 are enclosed to form a closed loop structure, the controller starts the circulating pump 45, and the circulating pump 45 drives the water in the closed loop structure to flow reversely, so that the impurities in the first filter 22 are directly flushed into the second filter 43 in the water outlet pipeline 30. After backwashing for a period of time, the two fourth electromagnetic valves 44 and the circulation pump 45 are closed, the two first electromagnetic valves 21 are opened simultaneously, the second electromagnetic valve 31 and the third electromagnetic valve 41 are opened, and at the moment, along with normal household entry of water, the water in the water outlet pipeline 30 carries impurities in the second filter 43 into the water return pipe.

In this embodiment, the circulation pump 45 is electrically connected to the controller.

In some embodiments, the first filter 22 may have a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, the first filter 22 is positioned between the two intermediate pipes 42 to ensure that impurities are introduced into the second filter 43 during the backwash operation.

In some embodiments, each of the solenoid valves may have a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, each of the first solenoid valve 21, the second solenoid valve 31, the third solenoid valve 41, and the fourth solenoid valve 44 is electrically connected to the controller.

In some embodiments, each of the above thermometers may be configured as shown in fig. 1 and 2. Referring to fig. 1 and 2, the first thermometer 23 and the second thermometer 32 are electrically connected to a controller.

In some embodiments, each of the above-described flowmeters may have a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, the first flowmeter 24 and the second flowmeter 33 are both electrically connected to the controller.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (7)

1. The remote monitoring feedback control system for heating is characterized by comprising an installation box, a water inlet pipeline, a water outlet pipeline and a matched controller; the water inlet pipeline is arranged in the installation box, two ends of the water inlet pipeline extend out of the installation box respectively, one end of the water inlet pipeline is used for being communicated with a water inlet pipe for heating, and the other end of the water inlet pipeline is communicated with a heating pipeline for a heating user; the water inlet pipe is internally provided with a first electromagnetic valve, a first filter, a first thermometer and a first flowmeter respectively; the water outlet pipeline is arranged in the installation box, two ends of the water outlet pipeline extend out of the installation box respectively, one end of the water outlet pipeline is used for being communicated with a water return pipe for heating, and the other end of the water outlet pipeline is communicated with a heating pipeline for heating users; and the water outlet pipeline is respectively provided with a second electromagnetic valve and a second thermometer second flowmeter.

2. The remote monitoring feedback control system for heating according to claim 1, wherein two of the first electromagnetic valves are provided, and the two first electromagnetic valves are arranged at intervals; the first filter is positioned between the two first electromagnetic valves.

3. The remote monitoring feedback control system for heating according to claim 2, further comprising a back flushing structure comprising a third solenoid valve, an intermediate line, a second filter, a fourth solenoid valve, and a circulation pump; the third electromagnetic valve is arranged on the water outlet pipeline and is arranged at intervals with the second electromagnetic valve; the two intermediate pipelines are arranged, the two intermediate pipelines are positioned between the two first electromagnetic valves, the two intermediate pipelines are positioned between the second electromagnetic valve and the third electromagnetic valve, and the two ends of each intermediate pipeline are respectively communicated with the water inlet pipeline and the water outlet pipeline; the second filter is arranged on the water outlet pipeline and is positioned between the two middle pipelines; the two fourth electromagnetic valves are arranged on the two middle pipelines respectively; the circulating pump is arranged on one of the intermediate pipelines.

4. A remote monitoring feedback control system for heating as set forth in claim 3 wherein said first filter is located between two intermediate lines.

5. A remote monitoring feedback control system for heating according to claim 3, wherein each of the first solenoid valve, the second solenoid valve, the third solenoid valve, and the fourth solenoid valve is electrically connected to the controller.

6. The remote monitoring feedback control system for heating according to claim 1, wherein the first thermometer and the second thermometer are each electrically connected to the controller.

7. The remote monitoring feedback control system for heating according to claim 1, wherein the first flow meter and the second flow meter are electrically connected to the controller.