CN210568772U

CN210568772U - Complementary trigeminy of multipotency source supplies system

Info

Publication number: CN210568772U
Application number: CN201921138623.XU
Authority: CN
Inventors: 李军
Original assignee: Yinchuan Aini Industrial Technology Development Co ltd
Current assignee: Yinchuan Aini Industrial Technology Development Co ltd
Priority date: 2019-07-19
Filing date: 2019-07-19
Publication date: 2020-05-19
Anticipated expiration: 2029-07-19

Abstract

The utility model belongs to the technical field of heating system, a complementary trigeminy of multipotency source supplies system is related to. The system comprises an energy storage water tank, an air source heat pump, a solar heat supply device, a living area heat supply pipe network, a pipeline system, a water temperature sensor system, a circulating water pump system and an electric valve system, wherein a first water inlet of the energy storage water tank is connected with a water outlet of the air source heat pump, a first water outlet of the energy storage water tank is connected with a water inlet of the air source heat pump, a second water inlet of the energy storage water tank is connected with a water outlet of the solar heat supply device, and a second water outlet of the energy storage water tank is connected with a. The system realizes linkage complementary heat supply of three heat supply systems, timely stores redundant heat generated by solar energy and reasonably distributes the redundant heat for use, improves the utilization rate of the solar energy, reduces the running time of an air source heat pump, and saves energy and running cost.

Description

Complementary trigeminy of multipotency source supplies system

Technical Field

The utility model belongs to the technical field of heating system, a complementary trigeminy of multipotency source supplies system is related to.

Background

With the progress of society and the improvement of living standard, the requirements of people on daily living environment are higher and higher, especially the requirements of people on hot water increase in summer and heating increase in winter. The existing resident heating system usually adopts a single solar heat collection mode to provide heat required by residents. In winter or cloudy days, the heat demand of residents in life cannot be met only by illumination; when the lighting condition is sufficient and the heat demand in the life of the residents is reduced, the redundant heat is wasted.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a complementary trigeminy of multipotency source supplies system, in time stores and rationally utilizes unnecessary heat, improves the utilization ratio of solar energy, energy saving and cost.

The utility model provides a technical problem as follows.

A multi-energy complementary triple co-generation system comprises an energy storage water tank, an air source heat pump, a solar heat supply device, a living area heat supply pipe network, a pipeline system, a water temperature sensor system, a circulating water pump system and an electric valve system; the pipeline system comprises a pipeline A, a pipeline B, a pipeline C, a pipeline D, a pipeline E and a pipeline F, the water temperature sensor system comprises a first water temperature sensor and a second water temperature sensor, the circulating water pump system comprises a first circulating water pump and a second circulating water pump, and the electric valve system comprises a first electric valve and a second electric valve; a first water inlet of the energy storage water tank is connected with a water outlet of the air source heat pump through a pipeline A, and a first water outlet is connected with a water inlet of the air source heat pump through a pipeline B; a second water inlet of the energy storage water tank is connected with a water outlet of the solar heat supply device through a pipeline C, and a second water outlet is connected with a water inlet of the solar heat supply device through a pipeline D; the water inlet end of the heat supply pipe network of the living area is connected to the pipeline of the pipeline D through the pipeline E, and the water outlet end of the heat supply pipe network of the living area is connected to the pipeline of the pipeline C through the pipeline F; the first water temperature sensor and the second water temperature sensor are respectively arranged on a water inlet pipeline in the air source heat pump and a pipeline of the pipeline F; the first circulating water pump and the second circulating water pump are respectively arranged on pipelines of the pipeline B and the pipeline C; the first electric valve and the second electric valve are respectively arranged on the pipelines of the pipeline C and the pipeline D; preferably, the first electric valve and the second electric valve are both electric two-way valves. By adopting the technical scheme, the air source heat pump and the solar water heater can be combined with the energy storage water tank to provide required heat for residential areas in a linkage manner, the utilization rate of solar energy is improved, and energy and operation cost are saved.

Furthermore, the system also comprises an automatic exhaust valve, and the top end of the energy storage water tank and a water outlet pipeline of the solar heat supply device are provided with the automatic exhaust valve; effectively avoiding the potential safety hazard caused by sudden pressure increase of a water storage pipeline or a device due to the existence of air.

Furthermore, the system also comprises a tap water pipe, and the pipelines of the energy storage water tank and the pipeline E are respectively connected with the tap water pipe; the water resources circulating in pipelines such as the energy storage water tank, the solar water heater and the like can be supplemented in time.

Furthermore, the system also comprises check valves, and the pipelines of the tap water pipes are provided with the check valves; effectively preventing water in the pipeline from flowing backwards into tap water used by residents in life.

Furthermore, the system also comprises ball valves, and in the pipeline system, the pipeline of each pipeline is provided with a ball valve; and each component in the system is convenient to repair and replace.

Furthermore, pressure gauges are arranged on the pipelines of the pressure gauge pipeline A and the pipeline C; the pressure on the pipeline can be monitored in real time, and the safety of the system is improved.

Furthermore, the system also comprises a drain valve, wherein the drain valve is arranged on the pipeline of the pipeline B; the redundant water in the air source heat pump pipeline can be discharged in time, and the operation safety is improved.

Furthermore, the number of the solar heat supplies is at least 2, a water inlet of each solar heat supply is connected to the pipeline of the pipeline D through a pipeline, and a water outlet of each solar heat supply is connected to the pipeline of the pipeline C through a pipeline; furthermore, the number of the air source heat pumps is at least 2, the water inlet of each air source heat pump is connected to the pipeline of the pipeline B through a pipeline, and the water outlet of each air source heat pump is connected to the pipeline of the pipeline A through a pipeline; through connecting multiunit solar energy heat supply ware and air source heat pump, the heating capacity of each heat supply mechanism in the reinforcing system makes entire system can be applied to the residential quarter of wider scope.

The utility model discloses complementary trigeminy of multipotency source supplies system's beneficial effect does: through the solar heat supplier, the combination of air source heat pump and energy storage water tank, in time with the unnecessary heat storage of solar energy production in energy storage water tank and rational distribution use, the complementary heat supply of linkage of three kinds of heating system has been realized, the problem of winter or cloudy day solar heating system heat supply inadequately has effectively been solved, and simultaneously, can avoid because the illumination condition is excellent, and the life hot water quantity is less, the heat loss and the waste that cause, the utilization ratio of solar energy has been improved, the operating time of air source heat pump has been reduced, energy and running cost have been practiced thrift.

Drawings

Fig. 1 is a schematic structural diagram of the multi-energy complementary triple co-generation system of the present invention.

The codes in the figures are respectively: the system comprises an energy storage water tank 1, an air source heat pump 2, a solar heat supply device 3, a living area heat supply pipe network 4, a pipeline A5-1, a pipeline B5-2, a pipeline C5-3, a pipeline D5-4, a pipeline E5-5, a pipeline F5-6, a first water temperature sensor 6-1, a second water temperature sensor 6-2, a first circulating water pump 7-1, a second circulating water pump 7-2, a first electric valve 8-1, a second electric valve 8-2, an automatic exhaust valve 9, a tap water pipe 10, a check valve 11, a ball valve 12, a pressure gauge 13 and a drain valve 14.

Detailed Description

As shown in fig. 1, a multi-energy complementary triple co-generation system comprises an energy storage water tank 1, an air source heat pump 2, a solar heat supply device 3, a living area heat supply pipe network 4, a pipeline system, a water temperature sensor system, a circulating water pump system, an electric valve system, an automatic exhaust valve 9, a tap water pipe 10, a check valve 11, a ball valve 12, a pressure gauge 13 and a drain valve 14; the pipeline system comprises a pipeline A5-1, a pipeline B5-2, a pipeline C5-3, a pipeline D5-4, a pipeline E5-5 and a pipeline F5-6, the water temperature sensor system comprises a first water temperature sensor 6-1 and a second water temperature sensor 6-2, the circulating water pump system comprises a first circulating water pump 7-1 and a second circulating water pump 7-2, the electric valve system comprises a first electric valve 8-1 and a second electric valve 8-2, and the first electric valve 8-1 and the second electric valve 8-2 are both electric two-way valves.

A first water inlet 1-11 of the energy storage water tank 1 is connected with a water outlet of the air source heat pump 2 through a pipeline A5-1, and a first water outlet 1-12 is connected with a water inlet of the air source heat pump 2 through a pipeline B5-2; a second water inlet 1-21 of the energy storage water tank 1 is connected with a water outlet of the solar heat supply device 3 through a pipeline C5-3, and a second water outlet 1-22 is connected with a water inlet of the solar heat supply device 3 through a pipeline D5-4; the water inlet end of the heat supply pipe network 4 of the living area is connected to the pipeline of the pipeline D5-4 through the pipeline E5-5, and the water outlet end is connected to the pipeline of the pipeline C5-3 through the pipeline F5-6.

A first water temperature sensor 6-1 and a second water temperature sensor 6-2 are respectively arranged on a water inlet pipeline in the air source heat pump 2 and a pipeline of the pipeline F5-6, a first circulating water pump 7-1 and a second circulating water pump 7-2 are respectively arranged on a pipeline B5-2 and a pipeline C5-3, and a first electric valve 8-1 and a second electric valve 8-2 are respectively arranged on a pipeline C5-3 and a pipeline D5-4; the automatic exhaust valves 9 are respectively arranged at the top end of the energy storage water tank 1 and the water outlet pipeline of the solar heat supply device 3, the tap water pipes 10 are respectively arranged on the energy storage water tank 1 and the pipelines of the pipelines E5-5, and the pipelines of the tap water pipes 10 are respectively provided with check valves 11; in the pipeline system, a ball valve 12 is arranged on each pipeline, a pressure gauge 13 is arranged on each pipeline of the pipeline A5-1 and the pipeline C5-3, and a drain valve 14 is arranged on each pipeline of the pipeline B5-2.

The number of the solar heat supply devices 3 is at least 2, the water inlet of each solar heat supply device 3 is connected to the pipeline of the pipeline D5-4 through a pipeline, and the water outlet is connected to the pipeline of the pipeline C5-3 through a pipeline; the number of the air source heat pumps 2 is at least 2, the water inlet of each air source heat pump 2 is connected to the pipeline of the pipeline B5-2 through a pipeline, and the water outlet of each air source heat pump 2 is connected to the pipeline of the pipeline A5-1 through a pipeline.

When the environment is in winter, the utility model discloses complementary trigeminy of multipotency source supplies the working process of system as follows.

1. When the air source heat pump 2 is started for the first time, when the first water temperature sensor 6-1 arranged in the air source heat pump 2 detects that the temperature of the water inlet is lower than the set temperature and the temperature difference between the set temperature and the starting temperature, the first circulating water pump 7-1 is started, then the air source heat pump 2 is started, water in the energy storage water tank 1 is heated, and heat is provided for each room in the heat supply pipe network 4 of the living area.

2. When the first water temperature sensor 6-1 arranged in the air source heat pump 2 detects that the temperature of the water inlet is greater than the set temperature plus the shutdown temperature difference, the air source heat pump 2 is shut down, and the first circulating water pump 7-1 continues to work, so that water in the energy storage water tank 1 continues to circulate, uninterrupted heat is provided for each room in the heat supply pipe network 4 of the living area, and the temperature of the room is ensured.

3. Meanwhile, in the solar heat supply device 3, if the sunlight is well illuminated and the domestic hot water is not used frequently, the temperature of the water in the solar heat supply device 3 is relatively high, so that the utilization rate of the solar energy is reduced; therefore, when the second water temperature sensor 6-2 on the pipeline F5-6 detects that the water temperature of the pipeline is higher than 80 ℃, the first electric valve 8-1 and the second electric valve 8-2 are opened, the second circulating water pump 7-2 is started, so that the water in the solar heat supply device 3 and the water in the energy storage water tank 1 continuously exchange heat to supplement the heat supplied by the air source heat pump 2 and reduce the running time of the air source heat pump 2; when the second water temperature sensor 6-2 on the pipeline F5-6 detects that the water temperature in the pipeline is less than 50 ℃ and more than 40 ℃, the second circulating water pump 7-2 stops working, and the first electric valve 8-1 and the second electric valve 8-2 are closed.

4. If the cloudy day is encountered in winter, the illumination condition is not good or the domestic water consumption is large, the solar heat supply device 3 can not provide hot water meeting the daily life requirements of people, at the moment, when the water temperature is less than 38 ℃, the first electric valve 8-1 and the second electric valve 8-2 are opened, the second circulating water pump 7-2 is started, water in the air source heat pump 2 and water in the solar heat supply device 3 circulate in the energy storage water tank 1 to supplement heat for the solar heat supply device 3, and the problem that the hot water supply is insufficient when the solar water heating system is cloudy or the water consumption is large is solved.

When the environment is in summer, the working process of the multi-energy complementary triple co-generation system is as follows.

1. The air source heat pump 2 is started for the first time, the air source heat pump 2 is started to a refrigeration mode, when the first water temperature sensor 6-1 arranged in the air source heat pump 2 detects that the temperature of a water inlet is higher than a set temperature plus a starting temperature difference, the first circulating water pump 7-1 is started, then the air source heat pump 2 is started to start refrigeration, and then cold energy is provided for each room in the heat supply pipe network 4 of the living area.

2. When the first water temperature sensor 6-1 arranged in the air source heat pump 2 detects that the temperature of the water inlet is less than the set temperature and the shutdown temperature difference, the air source heat pump 2 is shut down, and the first circulating water pump 7-1 continues to work, so that water in the refrigerating system continuously circulates to continuously provide cold for rooms of the heat supply pipe network 4 in the living area, and the temperature of the rooms is guaranteed.

3. The first electric valve 8-1 and the second electric valve 8-2 in the pipeline of the solar heat supply device 3 are normally closed, the second circulating water pump 7-2 is not started, the solar heat supply device 3 system and the refrigerating system do not exchange heat, and water in the solar heat supply device 3 is heated in a natural circulation mode to provide hot water required in life.

Claims

1. The multi-energy complementary triple co-generation system is characterized by comprising an energy storage water tank (1), an air source heat pump (2), a solar heat supply device (3), a living area heat supply pipe network (4), a pipeline system, a water temperature sensor system, a circulating water pump system and an electric valve system;

the pipeline system comprises a pipeline A (5-1), a pipeline B (5-2), a pipeline C (5-3), a pipeline D (5-4), a pipeline E (5-5) and a pipeline F (5-6), the water temperature sensor system comprises a first water temperature sensor (6-1) and a second water temperature sensor (6-2), the circulating water pump system comprises a first circulating water pump (7-1) and a second circulating water pump (7-2), and the electric valve system comprises a first electric valve (8-1) and a second electric valve (8-2);

a first water inlet (1-11) of the energy storage water tank (1) is connected with a water outlet of the air source heat pump (2) through a pipeline A (5-1), and a first water outlet (1-12) is connected with a water inlet of the air source heat pump (2) through a pipeline B (5-2);

a second water inlet (1-21) of the energy storage water tank (1) is connected with a water outlet of the solar heat supply device (3) through a pipeline C (5-3), and a second water outlet (1-22) is connected with a water inlet of the solar heat supply device (3) through a pipeline D (5-4);

the water inlet end of the living area heat supply pipe network (4) is connected to the pipeline of the pipeline D (5-4) through a pipeline E (5-5), and the water outlet end of the living area heat supply pipe network is connected to the pipeline of the pipeline C (5-3) through a pipeline F (5-6);

the first water temperature sensor (6-1) and the second water temperature sensor (6-2) are respectively arranged on a water inlet pipeline in the air source heat pump (2) and a pipeline of the pipeline F (5-6);

the first circulating water pump (7-1) and the second circulating water pump (7-2) are respectively arranged on pipelines of the pipeline B (5-2) and the pipeline C (5-3);

the first electric valve (8-1) and the second electric valve (8-2) are respectively arranged on the pipelines of the pipeline C (5-3) and the pipeline D (5-4).

2. The complementary trigeneration system of multipotency source of claim 1, characterized by, still include automatic air vent valve (9), all be provided with automatic air vent valve (9) on the top of energy storage water tank (1) and the outlet pipeline of solar heater (3).

3. The complementary trigeneration system of multipotency source of claim 1, characterized by, further includes water pipe (10), connect with water pipe (10) on the pipeline of said energy storage water tank (1), pipeline E (5-5) respectively.

4. The complementary trigeneration system of multipotency source of claim 3, characterized by, further comprises check valve (11), all be provided with check valve (11) on the pipeline of running water pipe (10).

5. The complementary trigeneration system of multipotency source of claim 1, characterized by, further comprising a ball valve (12), wherein in the piping system, each piping is provided with a ball valve (12) on its pipeline.

6. The complementary trigeneration system of multipotency source of claim 1, characterized by, further includes manometer (13), pipe-line of said pipeline A (5-1) and pipe-line C (5-3) all is provided with manometer (13).

7. The complementary trigeneration system of multipotency source of claim 1, characterized by, further comprises drain valve (14), said drain valve (14) is disposed on the pipeline of pipeline B (5-2).

8. The complementary trigeneration system of multipotency source of claim 1, characterized in that the number of solar heat supply devices (3) is at least 2, and the water inlet of each solar heat supply device (3) is connected to the pipeline of pipeline D (5-4) through a pipeline, and the water outlet is connected to the pipeline of pipeline C (5-3) through a pipeline.

9. The complementary trigeneration system of multipotency source of claim 1, characterized in that, the quantity of air source heat pump (2) is at least 2, and the water inlet of each air source heat pump (2) is connected to the pipeline of pipeline B (5-2) through the pipeline, and the water outlet is connected to the pipeline of pipeline A (5-1) through the pipeline.

10. The complementary trigeneration system of multipotency source of claim 1, characterized in that, the first electro valve (8-1) and the second electro valve (8-2) are both an electro two-way valve.