CN220750237U - Multifunctional complementary green low-carbon heating system - Google Patents

Abstract

The utility model relates to a multifunctional complementary green low-carbon heating system, which comprises an air source heat pump device, a high-temperature gas water heater, a radiator and a control device, wherein a water outlet pipe of the air source heat pump device is connected with the control device, a water inlet pipe and a water outlet pipe of the high-temperature gas water heater are both connected with the control device, the control device is connected with the water inlet pipe of the radiator, a water return pipe of the radiator is connected with the water return pipe of the air source heat pump device, the control device comprises a controller, a first temperature sensor and an actuating mechanism, the controller is connected with the first temperature sensor and the actuating mechanism, the first temperature sensor is used for detecting the water outlet temperature of the air source heat pump device, and the actuating mechanism is used for switching the connection between the water outlet pipe of the air source heat pump device and the water inlet pipe of the high-temperature gas water heater or the radiator. The utility model has reasonable structure, realizes high-quality heating while saving energy and protecting environment, and ensures the heating effect.

Description

Multifunctional complementary green low-carbon heating system

Technical Field

The utility model relates to the technical field of heat supply, in particular to a multifunctional complementary green low-carbon heat supply system.

Background

At present, most residential heating systems supply heat by a single heat source, more boilers and wall-mounted furnaces are adopted in the past, and along with the occurrence of environmental protection problems, policies such as 'coal changing electricity', 'coal changing gas', and the like are sequentially discharged from each region, so that heating systems with complementary functions are sequentially arranged, such as auxiliary energy systems such as a low-temperature air source, a ground source heat pump, solar energy, and the like, and a multifunctional complementary heating system is formed, thereby realizing the purposes of saving energy and reducing cost.

The air source heat pump and the gas wall-mounted furnace are matched for heating, so that the air source heat pump and the gas wall-mounted furnace are quite ideal in heating mode, but because the water temperature of the air source heat pump does not reach the heating requirement, the gas wall-mounted furnace needs to be manually switched at the moment, at present, the switching of the heating mode still needs to be manually switched, and the situation that the water temperature of the air source heat pump is insufficient when the water temperature is unknown exists is caused, so that the heating quality is reduced.

Disclosure of Invention

The utility model aims to provide a multifunctional complementary green low-carbon heating system, which solves the problems existing in the conventional multifunctional complementary heating system.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the multifunctional complementary green low-carbon heating system comprises an air source heat pump device, a high-temperature gas water heater, a radiator and a control device, wherein a water outlet pipe of the air source heat pump device is connected with the control device, a water inlet pipe and a water outlet pipe of the high-temperature gas water heater are both connected with the control device, the control device is connected with a water inlet pipe of the radiator, and a water return pipe of the radiator is connected with a water return pipe of the air source heat pump device; the control device comprises a controller, a first temperature sensor and an actuating mechanism, wherein the controller is connected with the first temperature sensor and the actuating mechanism, the first temperature sensor is used for detecting the water outlet temperature of the air source heat pump device, and the actuating mechanism is used for switching the connection between a water outlet pipe of the air source heat pump device and a water inlet pipe of the high-temperature gas water heater or radiator.

Further, the control device further comprises a shell, a cold water inlet of the gas water heater and a hot water outlet of the gas water heater are arranged at the upper end of the shell, an air source hot water inlet and a total outlet are arranged at the lower end of the shell, the actuating mechanism comprises an electric three-way valve, the electric three-way valve comprises a water inlet end, a first water outlet end and a second water outlet end, the water inlet end is connected with the air source hot water inlet through a pipeline, the first water outlet end is connected with the cold water inlet of the gas water heater through a pipeline, the second water outlet end is connected with the total outlet through a pipeline, and the hot water outlet of the gas water heater is connected with the total outlet.

Further, the temperature sensor is positioned in the shell and connected to a pipeline between the air source hot water inlet and the water inlet end.

Further, the air source heat pump device comprises an air source heat pump and an air energy water tank, the air source heat pump is connected with the air energy water tank, the air source hot water inlet is connected with the water outlet of the air energy water tank, and the water return pipe of the radiator is connected with the water return pipe of the air energy water tank.

Further, a circulating pump is arranged on a pipeline between the air source hot water inlet and the water outlet of the air energy water tank.

Further, the radiator is connected with a second sensor, and the second sensor is connected with the controller.

The utility model has the beneficial effects that:

according to the multifunctional complementary green low-carbon heat supply system, complementary heat supply is realized through the cooperation of the air source heat pump device and the high-temperature gas water heater, the air source heat pump device and the high-temperature gas water heater are connected with the control device, the first temperature sensor in the control device can detect the temperature of hot water output by the air source heat pump device in real time, when the temperature is smaller than the temperature required by heat supply, the water outlet pipe of the air source heat pump device is communicated with the water inlet pipe of the high-temperature gas water heater through the connection of the switching pipeline of the actuating mechanism, and the hot water is heated for the second time to reach the heat supply temperature, so that the heat supply effect is ensured.

Drawings

FIG. 1 is a schematic diagram of a multi-functional complementary green low carbon heating system of the present utility model;

FIG. 2 is a schematic diagram of a control device in the multi-functional complementary green low carbon heating system of the present utility model.

Name corresponding to each label in the figure:

1. the air source heat pump device, 11, an air source heat pump, 12, an air energy water tank, 2, a high-temperature gas water heater, 3, a radiator, 4, a control device, 41, a first temperature sensor, 42, a shell, 43, a gas water heater cold water inlet, 44, a gas water heater hot water outlet, 45, an air source hot water inlet, 46, a general outlet, 47, an electric three-way valve, 471, a water inlet end, 472, a first water outlet end, 473, a second water outlet end, 5, a circulating pump, 6 and a second sensor.

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 are derived by a person skilled in the art based on the embodiments of the utility model, fall within the scope of protection of the utility model.

Example 1

The multifunctional complementary green low-carbon heating system in the embodiment of the utility model realizes high-efficiency heating of a house by matching the air source heat pump device with the high-temperature gas water heater, and ensures heating quality on the premise of saving energy.

Specifically, as shown in fig. 1, the multifunctional complementary green low-carbon heat supply system comprises an air source heat pump device 1, a high-temperature gas water heater 2, a radiator 3 and a control device 4, wherein the air source heat pump device 1 is used as main equipment for heat supply, has the characteristics of energy conservation and high heat supply efficiency, but has the problem of insufficient heat supply temperature, and the high-temperature gas water heater 2 is used as auxiliary heat supply equipment, has the characteristics of low cost and high heat supply speed, and is complementary in two groups to realize high-quality heat supply.

In this embodiment, as shown in fig. 1 and 2, the water outlet pipe of the air source heat pump device 1 is connected with the control device 4, the water inlet pipe and the water outlet pipe of the high temperature gas water heater 2 are both connected with the control device 4, the control device 4 is connected with the water inlet pipe of the radiator 3, the water return pipe of the radiator 3 is connected with the water return pipe of the air source heat pump device 1, the control device 4 comprises a controller, a first temperature sensor 41 and an actuating mechanism, the first temperature sensor 41 can detect the water outlet temperature of the air source heat pump device 1, the actuating mechanism can switch the connection between the water outlet pipe of the air source heat pump device 1 and the water inlet pipe of the high temperature gas water heater 2 or the radiator 3, when the temperature detected by the first temperature sensor 41 accords with the heat supply temperature, the controller controls the actuating mechanism to act, when the temperature detected by the first temperature sensor 41 is lower than the heat supply temperature, the controller controls the actuating mechanism to act, so that the hot water enters the high temperature water heater 2 to perform secondary heating, thereby guaranteeing the heat supply temperature.

In this embodiment, the control device 4 further includes a housing 42, the housing 42 is disposed indoors, a cold water inlet 43 of the gas water heater and a hot water outlet 44 of the gas water heater are disposed at the upper end of the housing 42, an air source hot water inlet 45 and a total outlet 46 are disposed at the lower end of the housing 42, the actuator includes an electric three-way valve 47, the electric three-way valve 47 includes a water inlet end 471, a first water outlet end 472 and a second water outlet end 473, the water inlet end 471 is connected with the air source hot water inlet 45 through a pipeline, the first water outlet end 472 is connected with the cold water inlet 43 of the gas water heater through a pipeline, the second water outlet end 473 is connected with the total outlet 46 through a pipeline, and the gas water heater hot water outlet 44 is connected with the total outlet 46.

In the present embodiment, the first temperature sensor 41 is located in the housing 42 and connected to a pipe between the air source hot water inlet 45 and the water inlet 471, so that the temperature of the input hot water can be accurately detected.

As shown in fig. 1, the air source heat pump device 1 comprises an air source heat pump 11 and an air energy water tank 12, the air source heat pump 11 is connected with the air energy water tank 12, an air source hot water inlet 45 is connected with a water outlet of the air energy water tank 12, a water return pipe of the radiator 3 is connected with a water return pipe of the air energy water tank 12, meanwhile, a circulating pump 5 is arranged on a pipeline between the air source hot water inlet 45 and the water outlet of the air energy water tank 12, the circulating pump 5 is connected with a controller, and the circulation of hot water is realized through the circulating pump 5.

As shown in fig. 1, the radiator 3 is connected with a second sensor 6, the second sensor 6 is connected with a controller, the water temperature in the radiator 3 is monitored by the second sensor 6, frost cracking caused by too low water temperature in the radiator 3 when heat supply is not performed is avoided, and when the temperature detected by the second sensor 6 is too low, the controller controls an electric three-way valve 47, so that water in the air energy water tank 12 enters the high-temperature gas water heater 2 for heating, the low-temperature condition of the whole heat supply device is avoided, and the use safety is ensured.

The multifunctional complementary green low-carbon heating system is reasonable in structure, energy-saving and environment-friendly, realizes high-quality heating, and ensures the heating effect.

Claims (4)

1. A multifunctional complementary green low-carbon heating system is characterized in that: the high-temperature gas water heater comprises an air source heat pump device, a high-temperature gas water heater, a radiator and a control device, wherein a water outlet pipe of the air source heat pump device is connected with the control device, a water inlet pipe and a water outlet pipe of the high-temperature gas water heater are both connected with the control device, the control device is connected with a water inlet pipe of the radiator, and a water return pipe of the radiator is connected with a water return pipe of the air source heat pump device; the control device comprises a controller, a first temperature sensor and an actuating mechanism, wherein the controller is connected with the first temperature sensor and the actuating mechanism, the first temperature sensor is used for detecting the water outlet temperature of the air source heat pump device, and the actuating mechanism is used for switching the connection between a water outlet pipe of the air source heat pump device and a water inlet pipe of the high-temperature gas water heater or radiator; the control device further comprises a shell, a cold water inlet of the gas water heater and a hot water outlet of the gas water heater are arranged at the upper end of the shell, an air source hot water inlet and a total outlet are arranged at the lower end of the shell, the actuating mechanism comprises an electric three-way valve, the electric three-way valve comprises a water inlet end, a first water outlet end and a second water outlet end, the water inlet end is connected with the hot water inlet of the air source through a pipeline, the first water outlet end is connected with the cold water inlet of the gas water heater through a pipeline, the second water outlet end is connected with the total outlet through a pipeline, and the hot water outlet of the gas water heater is connected with the total outlet; the radiator is connected with a second sensor, and the second sensor is connected with the controller.

2. The multi-functional complementary green low carbon heating system of claim 1, wherein: the temperature sensor is positioned in the shell and connected to a pipeline between the hot water inlet of the air source and the water inlet end.

3. The multi-functional complementary green low carbon heating system of claim 2, wherein: the air source heat pump device comprises an air source heat pump and an air energy water tank, the air source heat pump is connected with the air energy water tank, the air source hot water inlet is connected with the water outlet of the air energy water tank, and the water return pipe of the radiator is connected with the water return pipe of the air energy water tank.

4. A multi-functional complementary green low carbon heating system according to claim 3, wherein: and a circulating pump is arranged on a pipeline between the air source hot water inlet and the water outlet of the air energy water tank.