CN222597423U - Energy-saving control device in energy system - Google Patents

Abstract

The utility model relates to the technical field of energy systems, specifically to an energy-saving control device in an energy system, comprising an energy transmission component and a branch control component, the energy transmission component comprising pipeline one, pipeline two, pipeline three, pipeline four and energy equipment, the branch control component comprising an adjustable flow valve, electric valve one, electric valve two, electric valve three, a return pipeline, a differential pressure gauge and a filter, the pipeline one is equipped with an adjustable flow valve, electric valve one, electric valve two, a differential pressure gauge and a filter, the pipeline one is connected to the return end of the energy equipment through the return pipeline, the electric valve three is installed on the return pipeline, the two input ends of the differential pressure gauge are respectively connected to the two sides of the filter, the differential pressure gauge is used to detect the pressure difference between the input end and the output end of the filter, the utility model has the effect of reducing the situation of transmitting more debris to the user end, is conducive to automatically monitoring and controlling the transmitted water, and is convenient for automatically handling blockage faults.

Description

Energy-saving control device in energy system

Technical Field

The utility model relates to the technical field of energy systems, in particular to an energy-saving control device in an energy system.

Background

The energy is in carrying out transmission in-process, and the heat-conducting medium of transmission adopts water to carry out more, and water carries out long-range transmission in energy system, and there is partial debris entering pipeline inside the source of water and the transmission in-process of water, and more debris can influence the heat conduction effect to easily cause the jam of pipeline, and after adding the filter, the filter long-term use, trouble and debris pile up the back, easily cause transmission department pressure too big and damage the part, need in time maintain, can waste partial energy.

Disclosure of utility model

(One) solving the technical problems

Aiming at the defects of the prior art, the utility model provides an energy-saving control device in an energy system, which has the advantages of reducing the condition of transmitting more sundries to a user side, being beneficial to automatically monitoring and controlling the transmitted water and being convenient for automatically processing the fault condition of blockage.

(II) technical scheme

In order to achieve the aim, the utility model provides the following technical scheme that the energy-saving control device in the energy system comprises an energy conveying component and a branch control component;

The energy conveying assembly comprises a first pipeline, a second pipeline, a third pipeline, a fourth pipeline and energy equipment, wherein the energy equipment is communicated with the second pipeline through the first pipeline, the third pipeline is communicated with the energy equipment through a plurality of the fourth pipelines, the second pipeline is communicated with the water inlet end of the user equipment, and the third pipeline is communicated with the water outlet end of the user equipment;

The branch control assembly comprises an adjustable throttle valve, an electric valve I, an electric valve II, an electric valve III, a water return pipeline, a differential pressure gauge and a filter, wherein the adjustable throttle valve, the electric valve I, the electric valve II, the differential pressure gauge and the filter are arranged on the pipeline I, the electric valve I and the electric valve II are located in a region between energy equipment and the filter, the water return ends of the pipeline I and the energy equipment are communicated through the water return pipeline, the electric valve III is arranged on the water return pipeline, the joint of the water return pipeline and the pipeline I is located in the region between the electric valve I and the electric valve II, two input ends of the differential pressure gauge are respectively communicated with two sides of the filter, and the differential pressure gauge is used for detecting pressure difference between the input end and the output end of the filter.

Preferably, the automatic water supply system further comprises a main path control assembly, wherein the main path control assembly comprises a second pressure gauge, a water pump and a third pressure gauge, the second pressure gauge, the water pump and the third pressure gauge are arranged on the second pipeline, and the second pressure gauge and the third pressure gauge are positioned on two sides of the water pump.

Preferably, the branch control assembly further comprises a pressure gauge I and an electric valve IV, and the pressure gauge I and the electric valve IV are arranged on the pipeline I.

Preferably, the main path control assembly further comprises a one-way valve and an unloading valve, the two-way valve and the unloading valve are arranged on the pipeline, and the unloading valve is located in a middle area of the one-way valve and the user side equipment.

Preferably, the main path control assembly further comprises an electric valve five, and a plurality of electric valves five are arranged on the pipeline four.

(III) beneficial effects

Compared with the prior art, the utility model provides an energy-saving control device in an energy system, which has the following beneficial effects:

According to the energy-saving control device in the energy system, heating or refrigerating is performed through the energy equipment, a heat conducting medium for refrigerating or heating is provided for a user side through the first pipeline and the second pipeline, the circulating heat conducting medium flows back to the inside of the energy equipment through the third pipeline, water is filtered at the filter, impurities entering the first pipeline in the circulating process are filtered, after more impurities are filtered, the pressure difference at two sides of the filter is increased, the pressure difference at two ends of the filter is conveniently detected, when the impurities are excessive or the impurities are failed, the third electric valve is opened, the second electric valve is closed, the transmitted water flows back to the energy equipment at the water return pipeline, the water is not sent to the user side, the condition that more impurities are transmitted to the user side is reduced, the automatic monitoring and the control of the transmitted water are facilitated, the automatic treatment of blocked fault conditions is facilitated, and the utilization of different energy sources and the maintenance are facilitated, so that the utilization rate of partial energy sources is facilitated to be saved, and the utilization rate is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model.

The drawing comprises a first pipeline, a second pipeline, a third pipeline, a fourth pipeline, a5 energy source device, a6 adjustable throttle valve, a7 electric valve, a first 8 electric valve, a second electric valve, a 9 electric valve, a third electric valve, a 10 return water pipeline, a 11 differential pressure meter, a 12 filter, a 13 pressure meter, a 14 electric valve, a fourth electric valve, a 15 pressure meter, a second 16 water delivery pump, a 17 pressure meter, a third 18 one-way valve, a 19 unloading valve, a 20 electric valve and a fifth electric valve.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

Referring to fig. 1, an energy saving control device in an energy system includes an energy conveying assembly and a bypass control assembly.

The energy conveying assembly comprises a first pipeline 1, a second pipeline 2, a third pipeline 3, a fourth pipeline 4 and energy equipment 5, wherein the energy equipment 5 is communicated with the second pipeline 2 through the first pipeline 1, the third pipeline 3 is communicated with the energy equipment 5 through a plurality of the fourth pipelines 4, the second pipeline 2 is communicated with the water inlet end of the user equipment, and the third pipeline 3 is communicated with the water outlet end of the user equipment.

The branch control component comprises an adjustable throttle valve 6, an electric valve I7, an electric valve II 8, an electric valve III 9, a water return pipeline 10, a differential pressure meter 11 and a filter 12, wherein the adjustable throttle valve 6, the electric valve I7, the electric valve II 8, the differential pressure meter 11 and the filter 12 are arranged on the pipeline I1, the electric valve I7 and the electric valve II 8 are positioned in the area between the energy source equipment 5 and the filter 12, the water return ends of the pipeline I1 and the energy source equipment 5 are communicated through the water return pipeline 10, the electric valve III 9 is arranged on the water return pipeline 10, the joint of the water return pipeline 10 and the pipeline I1 is positioned in the area between the electric valve I7 and the electric valve II 8, the two input ends of the differential pressure meter 11 are respectively communicated with the two sides of the filter 12, the differential pressure meter 11 is used for detecting the pressure difference between the input end and the output end of the filter 12, the differential pressure meter 11 is in the model such as 490A-1, the energy source equipment 5 is preferably equipment for heating or refrigerating water, the device can adopt various energy sources for conversion, such as a solar device, a device for converting wind energy into electric energy for heating, a device for heating by utilizing geothermal energy, a device for heating by utilizing combustion thermal energy and the like, such as a solar water heater, a refrigerator, a cooling tower, a geothermal pump, a boiler and the like for temperature change of heat conducting media, the energy equipment 5 is provided with a plurality of water outlet ends and water return ends, the heat conducting media can form the effect of circulation transmission, a pump set capable of driving water circulation is preferably arranged in the energy equipment 5, the filter 12 is preferably of a type with a pollution indicator lamp, the type of the filter 12 is preferably SY-BAGLQ-01, the heating or the refrigerating is carried out through the energy equipment 5, the heat conducting media for refrigerating or heating are provided for a user end through a first pipeline 1 and a second pipeline 2, and the heat conducting media for refrigerating or heating are arranged through a third pipeline 3, the circulating heat conducting medium flows back to the inside of the energy equipment 5, the filter 12 is used for filtering water, part of impurities entering the first pipeline 1 in the circulating process are filtered, after more impurities are filtered, the pressure difference at two sides of the filter 12 is increased, the pressure difference at two ends of the filter 12 is conveniently detected, when the impurities are excessive or the impurities are failed, the electric valve III 9 is opened, the electric valve II 8 is closed, the transmitted water flows back to the energy equipment 5 at the water return pipeline 10, the water is not sent to the user side any more, the condition that more impurities are transmitted to the user side is further reduced, the automatic monitoring and control of the transmitted water are facilitated, the blocked failure condition is conveniently processed automatically, and the utilization of different energy sources and the structure beneficial to maintenance are facilitated, so that part of energy sources are saved, and the utilization rate is improved.

The energy-saving control device also comprises a main path control component, wherein the main path control component comprises a second pressure gauge 15, a water delivery pump 16 and a third pressure gauge 17, the water delivery pump 16 can control the speed of delivering water, the second pressure gauge 15, the water delivery pump 16 and the third pressure gauge 17 are arranged on the second pipeline 2, the second pressure gauge 15 and the third pressure gauge 17 are positioned on two sides of the water delivery pump 16, the water delivery pump 16 is a variable-frequency pump or a variable-flow pump, the water delivery pump 16 is a model with corresponding power and caliber according to the actual use scene, the model is electrically connected with a controller, the controller is preferably a computer, a frequency converter or other control devices capable of controlling the flow of the water delivery pump 16 are preferably arranged, the effect of automatically controlling the flow of the water delivery pump 16 is convenient, the second pressure gauge 15 and the third pressure gauge 17 are of the type capable of sending out digital signals, can convert detected data into computer-usable data, are preferably carried out in an RS485 or RS232 communication mode, are electrically connected with a controller, are preferably provided with wireless transmission modules, transmit the data to a computer in a wireless mode, such as a pressure gauge with the model number of YL-821ER or JD-ZF-50, detect the pressure at two ends of the water delivery pump 16 through the second pressure gauge 15 and the third pressure gauge 17, and cooperate with a program of the computer to carry out data monitoring, and can control the flow of the water delivery pump 16 after monitoring, so that the water delivery pump 16 can carry out water transmission with reasonable transmission efficiency.

The branch control assembly further comprises a first pressure gauge 13 and a fourth electric valve 14, the first pressure gauge 13 and the fourth electric valve 14 are arranged on the first pipeline 1, pipeline pressure of the first pipeline 1 is detected through the first pressure gauge 13, heat conduction is controlled to be conducted through different branches by opening and closing the corresponding fourth electric valve 14, the pressure of the first pipeline 1 is detected through the arrangement of the first pressure gauge 13, pipeline pressure detection is further facilitated, maintenance is facilitated, and the first pressure gauge 13 is preferably in the same mode as the second pressure gauge 15 and the third pressure gauge 17.

The main path control assembly further comprises a one-way valve 18 and an unloading valve 19, the one-way valve 18 and the unloading valve 19 are arranged on the second pipeline 2, the unloading valve 19 is located in the relative middle area of the one-way valve 18 and the user side equipment, the unloading valve 19 is preferably in an electric mode, the transmitted water is only transmitted along one direction through the arrangement of the one-way valve 18, after the user side equipment fails, the pressure is increased, the liquid cannot flow back to cause larger damage of the system, and through the arrangement of the unloading valve 19, when the pressure of the user side equipment is overlarge, the unloading valve 19 can be opened to discharge water, and the safety effect of the equipment in use is further improved.

The main way control assembly further comprises an electric valve five 20, a plurality of electric valves five 20 are arranged on the pipeline four 4, the on-off of the pipeline four 4 can be controlled through the arrangement of the electric valves five 20, and then when different branches are used, the corresponding electric valves five 20 are opened, so that the control of the pipeline is facilitated.

Among them, the first electric valve 7, the second electric valve 8, the third electric valve 9 and the fourth electric valve 14 are preferably electric shut-off valves.

When the energy source device is used, the corresponding electric valve IV 14 is opened, energy is conveyed by utilizing different branches, when the fact that the indication of the pressure difference meter 11 is large is detected, the electric valve III 9 is opened, the electric valve II 8 is closed, and the conveyed liquid is conveyed back to the energy source device 5 through the water return pipeline 10.

The adjustable throttle valve 6, the first electric valve 7, the second electric valve 8, the third electric valve 9, the differential pressure meter 11, the filter 12, the first pressure meter 13, the fourth electric valve 14, the second pressure meter 15, the water conveying pump 16, the third pressure meter 17 and the unloading valve 19 are all electrically connected, the connection mode can adopt a wired optical fiber transmission or wireless transmission mode, a client side and a server side are set up, data signals are transmitted between the server and the client side, transmission flow of each detection data and each end is controlled, and data acquisition and centralized processing are facilitated.

It should be noted that references in the specification to "one embodiment," "an example embodiment," "some embodiments," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Furthermore, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.

It should be noted that the above embodiments are merely for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the above embodiments, it should be understood by those skilled in the art that the technical solution described in the above embodiments may be modified or some or all of the technical features may be equivalently replaced, and these modifications or substitutions do not make the essence of the corresponding technical solution deviate from the scope of the technical solution of the embodiments of the present application.

Claims (5)

1. An energy-saving control device in an energy system, characterized in that it includes an energy transmission component and a branch control component; The energy transmission component comprises pipeline one (1), pipeline two (2), pipeline three (3), pipeline four (4) and energy equipment (5), the energy equipment (5) and pipeline two (2) are connected via pipeline one (1), pipeline three (3) and energy equipment (5) are connected via a plurality of pipeline fours (4), pipeline two (2) and a water inlet of a user-end device are connected, and pipeline three (3) and a water outlet of the user-end device are connected; The branch control assembly comprises an adjustable flow valve (6), an electric valve 1 (7), an electric valve 2 (8), an electric valve 3 (9), a return pipe (10), a differential pressure gauge (11) and a filter (12). The adjustable flow valve (6), the electric valve 1 (7), the electric valve 2 (8), the differential pressure gauge (11) and the filter (12) are installed on the pipe 1 (1). The electric valve 1 (7) and the electric valve 2 (8) are located in the area between the energy device (5) and the filter (12). The pipe 1 (1) and the return pipe of the energy device (5) are connected through the return pipe (10). The electric valve 3 (9) is installed on the return pipe (10). The connection between the return pipe (10) and the pipe 1 (1) is located in the area between the electric valve 1 (7) and the electric valve 2 (8). The two input ends of the differential pressure gauge (11) are respectively connected to the two sides of the filter (12). The differential pressure gauge (11) is used to detect the pressure difference between the input end and the output end of the filter (12). 2. An energy-saving control device in an energy system according to claim 1, characterized in that it also includes a main line control component, the main line control component includes a second pressure gauge (15), a water delivery pump (16) and a third pressure gauge (17), the water delivery pump (16) can control the speed of water delivery, and the second pressure gauge (15), the water delivery pump (16) and the third pressure gauge (17) are installed on the second pipeline (2), and the second pressure gauge (15) and the third pressure gauge (17) are located on both sides of the water delivery pump (16). 3. An energy-saving control device in an energy system according to claim 1, characterized in that: the branch control component also includes a pressure gauge (13) and an electric valve (14), and the pressure gauge (13) and the electric valve (14) are installed on the pipeline (1). 4. An energy-saving control device in an energy system according to claim 2, characterized in that: the main line control component also includes a one-way valve (18) and a unloading valve (19), and the one-way valve (18) and the unloading valve (19) are installed on the pipeline (2), and the unloading valve (19) is located in the middle area between the one-way valve (18) and the user-end device. 5. The energy-saving control device in an energy system according to claim 2, characterized in that: the main circuit control component also includes an electric valve five (20), and a plurality of electric valves five (20) are installed on the pipeline four (4).