CN113418250A

CN113418250A - Multi-energy complementary heat storage and connection heat pump air conditioning system

Info

Publication number: CN113418250A
Application number: CN202110563212.0A
Authority: CN
Inventors: 吴林森; 唐华强; 吴晋兰
Original assignee: Carbon Neutral Green Building Technology Suzhou Co ltd
Current assignee: Carbon Neutral Green Building Technology Suzhou Co ltd
Priority date: 2021-05-24
Filing date: 2021-05-24
Publication date: 2021-09-21

Abstract

The invention discloses a multi-energy complementary storage heat pump air conditioning system, which comprises an energy storage water tank and a household ground source heat pump, wherein the household ground source heat pump comprises a ground source heat pump heat exchanger; the household ground source heat pump and the energy storage water tank form a loop system through a water-passing waterway; the formed loop system exchanges an underground heat source through a ground source heat pump heat exchanger; and the heat source after heat exchange in the household ground source heat pump is introduced into the ground heating system and the fresh air system. The invention provides a multi-energy complementary heat storage and connection heat pump air-conditioning system which can effectively guarantee the heating and refrigerating effects of the air-conditioning system.

Description

Multi-energy complementary heat storage and connection heat pump air conditioning system

Technical Field

The invention relates to the field of multi-energy complementary heat storage and connection heat pump air conditioning systems.

Background

The air conditioning system is seen everywhere in modern society, and the air conditioner cools the indoor room where people live in summer and heats the indoor room in winter so as to ensure the effect of comfortable living environment; and if the water temperature is not enough in winter, the air source heat pump is required to heat the water temperature of the air conditioning system, and the water temperature can be quickly adjusted by the heat source with a certain temperature of the ground source heat pump, so that the appropriate temperature can be ensured indoors, and the living comfort level is improved.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects in the prior art, the invention provides the multi-energy complementary heat storage and connection heat pump air-conditioning system which can effectively guarantee the heating and refrigerating effects of the air-conditioning system.

The technical scheme is as follows: in order to achieve the purpose, the technical scheme of the invention is as follows:

the multi-energy complementary storage heat pump air conditioning system comprises an energy storage water tank and a household ground source heat pump, wherein the household ground source heat pump comprises a ground source heat pump heat exchanger; the household ground source heat pump and the energy storage water tank form a loop system through a water-passing waterway; the formed loop system exchanges an underground heat source through a ground source heat pump heat exchanger; and the heat source after heat exchange in the household ground source heat pump is introduced into the ground heating system and the fresh air system.

Further, the solar energy heat pump system comprises a solar energy system and an air energy heat pump; the energy storage water tank is respectively communicated with the solar system and the air energy heat pump; the energy storage water tank is connected with a plurality of household ground source heat pumps in series; the water in the household ground source heat pump is conveyed to the indoor of a user after the temperature of the water is adjusted by the solar energy system and the air energy heat pump through the energy storage water tank.

The fresh air system comprises a blowing structure and an energy collecting structure; the energy gathering structure comprises an energy gathering plate and a lifting structure; a cavity is formed in the energy-gathering plate; the cavity is communicated with a water guide pipeline of the fresh air system; a plurality of through holes are formed in the side wall of the energy collecting plate at intervals; elastic membranes are correspondingly arranged in the through holes; the moving end of the lifting structure drives the elastic film to come in and go out of the cavity back and forth, and the blowing structure blows hot air or cold air condensed in the elastic film indoors; the water guide pipe of the fresh air system is connected in series with the plurality of cavities; the edge of the through hole protrudes into the cavity to form a convex groove; the convex groove is correspondingly and fixedly provided with an elastic film; a condensation chamber is formed between the inner part of the convex groove and the elastic membrane; the condensation chambers are positioned in the range of the cavity and are open to be communicated with the outside.

Furthermore, a lifting structure is arranged among a plurality of through holes on the side wall of the energy gathering plate; the lifting structure comprises a fixed rod and a telescopic rod; one end of the fixed rod is fixed on the side wall of the energy gathering plate; a connecting block is fixedly arranged at the other end of the fixed rod; the telescopic device on the connecting block is in driving connection with one end of the telescopic rod; the other end of the telescopic rod is correspondingly embedded into the convex groove; the embedded end of the telescopic rod is fixed in the middle of the elastic membrane through a semicircular sheet; the telescopic rod drives the elastic membrane to move to push condensed hot air or cold air in the condensation chamber; a plurality of the open areas of the condensation chambers form diffusion zones.

Further, the blowing structure comprises a blowing fan; the blowing fan is correspondingly arranged on the mounting plate of the fresh air system; the blowing direction of the blowing fan is intersected with the diffusion area, the blowing fan is arranged close to one side of the energy collecting plate, and the blowing fan blows to the diffusion area in an inclined mode towards one side far away from the energy collecting plate.

Further, the floor heating system comprises a radiation plate; the radiation plates are respectively paved and installed in the floor and the ceiling of the house; the opposite radiation plates respectively conduct and radiate hot air or cold air to the room; the radiation plate comprises a mounting plate; a filling groove is formed in the mounting plate; capillary tubes are correspondingly filled in the filling grooves; the mounting plates are mutually spliced to form a radiation plate, and the capillaries are correspondingly spliced and communicated; the capillary tubes are respectively communicated with the water through pipes for circulation.

Furthermore, the bottom of the filling groove is rectangular, and the relative top of the filling groove is semicircular; the top of the filling groove is arranged in a chamber with a corresponding direction adjustment; an isolation block is fixedly arranged on one side of the capillary tube corresponding to the bottom of the filling groove; a heat insulating material is arranged between the isolation block and the bottom of the filling groove; the capillary tube and the isolation block are arranged in an integrated structure; a plurality of interlayers are arranged in the isolation blocks at intervals, and are arranged in a hollow mode; the interlayer layers are isolated by heat resistance blocks; the section of the interlayer is arc-shaped, and the interlayer is correspondingly adapted to the bottom of the capillary;

the bottom of the isolation block is provided with a vacuum layer; the vacuum layer and the interlayer are arranged at intervals, and a heat insulation layer is clamped between the vacuum layer and the interlayer; the plurality of vacuum layers are arranged at intervals along the extending direction of the capillary; the vacuum layers and the interlayer are arranged in a staggered mode, and the heat resistance block is right opposite to the middle of the vacuum layers; the vacuum layer is arranged in parallel to the bottom of the filling groove.

Furthermore, a plurality of slotted holes are formed in the top of the filling groove; a plurality of bulges are arranged on the side wall of the capillary tube corresponding to the positions of the slotted holes; the bulges are correspondingly embedded into the groove holes; the cavity inside the bulge is communicated with the inside of the capillary; the heat conducting rods on the side walls of the protrusions are correspondingly inserted into the inner walls of the slotted holes.

Has the advantages that: the invention can complement the function of adjusting the indoor temperature through a plurality of energy sources in the air conditioning system; including but not limited to the following benefits:

1) when water is introduced into the water guide pipe and the cavity, the temperature of the gas in the condensation chamber can be correspondingly reduced or increased, and the temperature of the gas in the condensation chamber is higher or lower than that of the gas at the periphery of the energy-gathering plate, so that the temperature in the condensation chamber can be quickly adjusted after the gas in the condensation chamber is pushed and extruded;

2) the telescopic link passes through the semicircle piece and drives the corresponding cavity that stretches into of elastic membrane in, condenses steam or air conditioning in the cavity like this, then the telescopic link drives the elastic membrane through the semicircle piece and pushes away the gas blowout of condensing in the cavity, spun gas is in the diffusion zone, then blows off indoor through blowing off the structure, just so can adjust indoor temperature.

Drawings

FIG. 1 is a diagram of a multi-energy complementary heat storage and connection heat pump air conditioning system;

FIG. 2 is a diagram of a fresh air system;

FIG. 3 is a view showing a structure of a diffusion region;

FIG. 4 is a drawing block diagram;

FIG. 5 is a view showing the structure of a radiation plate;

FIG. 6 is a view showing the structure of a capillary tube;

FIG. 7 is a view showing a structure of a vacuum layer.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

As shown in figures 1-7: the multi-energy complementary storage heat pump air conditioning system comprises an energy storage water tank 4 and a household ground source heat pump 6, wherein the household ground source heat pump 6 comprises a ground source heat pump heat exchanger; the household ground source heat pump 6 and the energy storage water tank 4 form a loop system through a water-passing waterway; the formed loop system exchanges an underground heat source through a ground source heat pump heat exchanger; and the heat source after heat exchange in the household ground source heat pump 6 is introduced into the ground heating system 3 and the fresh air system 7.

The solar energy heat pump system further comprises a solar energy system 5 and an air energy heat pump 8; the energy storage water tank 4 is respectively communicated with the solar energy system 5 and the air energy heat pump 8; the energy storage water tank 4 is connected with a plurality of household ground source heat pumps 6 in series; the water in the household ground source heat pump 6 is conveyed to the indoor of a user after the temperature of the water is adjusted by the solar energy system 5 and the air energy heat pump 6 through the energy storage water tank 4. The water temperature of the energy storage water tank in winter is maintained through solar energy, when the water temperature is not enough to be maintained through the solar energy in winter, the air source heat pump is started to heat, the energy is saved in winter and the water temperature is maintained at a certain temperature throughout the year by the ground source heat pump, and when summer comes, the water temperature is cooled through the adjustment of the ground source heat pump and the air source heat pump; therefore, the water in the power heat pump has a certain temperature, so that the heating energy consumption of the water can be reduced in winter, and the energy consumption of cooling the water can be reduced in summer.

The fresh air system 7 comprises a blowing structure 1 and an energy collecting structure 2; the energy gathering structure 2 comprises an energy gathering plate 21 and a pulling structure 22; a cavity 211 is formed in the energy collecting plate 21; the cavity 211 is communicated with a water guide pipeline of the fresh air system 7; a plurality of through holes 212 are formed in the side wall of the energy collecting plate 21 at intervals; an elastic film 213 is correspondingly arranged in the through hole 212; the moving end of the lifting structure 22 drives the elastic film 213 to move back and forth into and out of the cavity 211, and the blowing structure 1 blows the condensed hot air or cold air in the elastic film 213 indoors. The lifting structure carries and pushes out cold air or hot air formed in the elastic membrane, and then the blowing structure blows the hot air or the cold air into a room, so that the indoor air can be adjusted, and the heat preservation or cooling effect is achieved.

The water guide pipes of the fresh air system 7 are connected in series with the plurality of cavities 211; the edge of the through hole 212 protrudes into the cavity 211 to form a convex groove 214; the convex groove 214 is correspondingly and fixedly provided with an elastic film 213; a condensation chamber 215 is formed between the inside of the groove 214 and the elastic membrane 213. A plurality of said condensation chambers 215 are located within the cavity 211, and said condensation chambers 215 are open to the outside. When water is introduced into the water guide pipe and the cavity, the temperature of the gas in the condensation chamber can be correspondingly reduced or increased, and the temperature of the gas in the condensation chamber is higher or lower than that of the gas at the periphery of the energy collecting plate, so that the temperature in the condensation chamber can be quickly adjusted after the gas in the condensation chamber is pushed and extruded.

A lifting structure 22 is arranged among a plurality of through holes 212 on the side wall of the energy collecting plate 21; the lifting structure 22 comprises a fixing rod 221 and an expansion rod 222; one end of the fixing rod 221 is fixed on the side wall of the energy gathering plate 21; the other end of the fixed rod 221 is fixedly provided with a connecting block 223; the telescopic device on the connecting block 223 is in driving connection with one end of the telescopic rod 222; the other end of the telescopic rod 222 is correspondingly embedded into the convex groove 214; the embedded end of the expansion link 222 is fixed in the middle of the elastic membrane 213 through a semicircular sheet 224; the expansion rod 222 drives the elastic membrane 213 to move and push out condensed hot air or cold air in the condensation chamber 215. The telescopic rod drives the elastic membrane to correspondingly extend into the cavity through the semicircular sheet, so that hot air or cold air is condensed in the condensation cavity, then the telescopic rod drives the elastic membrane to push the air in the condensation cavity to be sprayed out through the semicircular sheet, and a plurality of diffusion areas 216 are formed in the open range of the condensation cavity 215; the sprayed gas is in the diffusion area and then is blown out to the room through the blowing structure, so that the temperature in the room can be adjusted.

The blowing structure 1 comprises a blowing fan 11; the blowing fan 11 is correspondingly arranged on the mounting plate of the fresh air system 7; the blowing direction of the blowing fan 11 is intersected with the diffusion area 216, the blowing fan 11 is arranged close to one side of the energy collecting plate 21, and the blowing fan 11 obliquely blows to the diffusion area 216 towards one side far away from the energy collecting plate 21; by blowing away the gas in the diffusion area, the indoor temperature can be adjusted more quickly, and a better heat preservation effect can be achieved.

The floor heating 3 comprises a radiation plate 31; the radiation plates 31 are respectively paved and installed in the floor and the ceiling of the house; the opposite radiation plates 31 respectively conduct and radiate hot air or cold air to the indoor space; the radiation plate 31 includes a mounting plate 32; a filling groove 321 is formed in the mounting plate 32; capillary tubes 322 are correspondingly filled in the filling grooves 321; the plurality of mounting plates 32 are spliced with each other to form the radiation plate 31, and the plurality of capillaries 322 are correspondingly spliced and communicated; the capillary tubes 322 are respectively communicated with the water pipes for circulation. Cold flow or hot flow is conveyed by the capillary tube to flow in the radiation plate, so that the indoor temperature can be reduced or increased, and the indoor temperature can be further ensured.

The bottom of the filling groove 321 is rectangular, and the top of the filling groove 321 is semicircular; the top of the filling groove 321 is correspondingly arranged towards the adjusted chamber; an isolation block 33 is fixedly arranged on one side of the capillary 322 corresponding to the bottom of the filling groove 321; a heat insulating material is arranged between the isolation block 33 and the bottom of the filling groove 321; the capillary tube 322 and the isolation block 33 are arranged in an integrated structure; a plurality of interlayer layers 331 are arranged in the isolation block 33 at intervals, and the interlayer layers 331 are arranged in a hollow manner; the interlayers 331 are isolated by heat resistant blocks 332; the section of the interlayer 331 is arc-shaped, and the interlayer 331 is correspondingly adapted to the bottom of the capillary 322; the heat is blocked by the interlayer, so that the heat loss in the capillary tube is reduced, and the heat loss caused by mutual contact between the conductors can be avoided.

The bottom of the isolation block 33 is provided with a vacuum layer 333; the vacuum layer 333 is arranged at a distance from the interlayer, and an insulating layer 334 is clamped between the vacuum layer 333 and the interlayer 331; a plurality of vacuum layers are arranged at intervals along the extending direction of the capillary tube 322; the vacuum layers 333 and the interlayer 331 are arranged in a staggered manner, and the heat resistance block 332 is opposite to the middle part of the vacuum layers 333; the vacuum layer 333 is arranged parallel to the bottom of the filling groove 321; the heat after the interlayer blocks carries out heat radiation through the vacuum layer, so that the heat transfer loss between the conductors is reduced through the interlayer firstly, and then the heat loss caused by gas convection is reduced through the vacuum layer, so that the heat exchange loss or the heat loss can be prevented only by small part of heat through the heat radiation form loss through the vacuum layer isolation.

The top of the filling groove 321 is provided with a plurality of groove holes 323; a plurality of protrusions 324 are arranged on the side wall of the capillary 322 corresponding to the positions of the slotted holes 323; the protrusion 324 is correspondingly embedded into the slot 323; the cavity 325 inside the protrusion 324 communicates with the inside of the capillary 322; a plurality of heat conducting rods 326 on the side walls of the bulges 324 are correspondingly inserted into the inner walls of the slotted holes 323; the contact area is increased through the bulges and the heat conducting rods, so that heat can be transferred to the indoor space needing temperature adjustment, and the temperature can be adjusted better.

The above description is of the preferred embodiment of the present invention and it will be apparent to those of ordinary skill in the art that several modifications and variations can be made without departing from the principles of the invention and these modifications and variations are also considered to be within the scope of the invention.

Claims

1. Complementary heat pump air conditioning system that allies oneself with that holds of multipotency source, its characterized in that: the system comprises an energy storage water tank (4) and a household ground source heat pump (6), wherein the household ground source heat pump (6) comprises a ground source heat pump heat exchanger; the household ground source heat pump (6) and the energy storage water tank (4) form a loop system through a water-passing waterway; the formed loop system exchanges an underground heat source through a ground source heat pump heat exchanger; and the heat source after heat exchange in the household ground source heat pump (6) is introduced into the ground heating system (3) and the fresh air system (7).

2. The multi-energy complementary heat storage and pump air conditioning system of claim 1, wherein: the solar energy heat pump system further comprises a solar energy system (5) and an air energy heat pump (8); the energy storage water tank (4) is respectively communicated with the solar system (5) and the air energy heat pump (8); the energy storage water tank (4) is connected with a plurality of household ground source heat pumps (6) in series; the water in the household ground source heat pump (6) is conveyed to the indoor of a user after the temperature of the water is adjusted by the solar energy system (5) and the air energy heat pump (6) through the energy storage water tank (4).

3. The multi-energy complementary heat storage and pump air conditioning system of claim 2, wherein: the fresh air system (7) comprises a blowing structure (1) and an energy collecting structure (2); the energy gathering structure (2) comprises an energy gathering plate (21) and a pulling structure (22); a cavity (211) is formed in the energy-gathering plate (21); the cavity (211) is communicated with a water guide pipeline of the fresh air system (7); a plurality of through holes (212) are formed in the side wall of the energy collecting plate (21) at intervals; an elastic membrane (213) is correspondingly arranged in the through hole (212); the moving end of the lifting structure (22) drives the elastic film (213) to come in and go out of the cavity (211), and the blowing structure (1) blows hot air or cold air condensed in the elastic film (213) indoors.

4. The multi-energy complementary heat storage and pump air conditioning system of claim 3, wherein: the water guide pipes of the fresh air system (7) are connected in series with the plurality of cavities (211); the edge of the through hole (212) protrudes into the cavity (211) to form a convex groove (214); the convex groove (214) is correspondingly and fixedly provided with an elastic film (213); a condensation chamber (215) is formed between the inner part of the convex groove (214) and the elastic membrane (213); a plurality of the condensation chambers (215) are arranged in the range of the cavity (211), and the condensation chambers (215) are communicated with the outside in an opening mode.

5. The multi-energy complementary heat storage and pump air conditioning system of claim 4, wherein: a lifting structure (22) is arranged among a plurality of through holes (212) on the side wall of the energy-gathering plate (21); the lifting structure (22) comprises a fixed rod (221) and an expansion rod (222); one end of the fixing rod (221) is fixed on the side wall of the energy-gathering plate (21); the other end of the fixed rod (221) is fixedly provided with a connecting block (223); the telescopic device on the connecting block (223) is in driving connection with one end of the telescopic rod (222); the other end of the telescopic rod (222) is correspondingly embedded into the convex groove (214); the embedded end of the telescopic rod (222) is fixed in the middle of the elastic membrane (213) through a semicircular sheet (224); the telescopic rod (222) drives the elastic film (213) to move and push condensed hot air or cold air in the condensation chamber (215); a plurality of said condensation chambers (215) open into a diffusion zone (216).

6. The multi-energy complementary heat storage and pump air conditioning system of claim 5, wherein: the blowing structure (1) comprises a blowing fan (11); the blowing fan (11) is correspondingly arranged on the mounting plate of the fresh air system (7); the blowing direction of the blowing fan (11) is intersected with the diffusion area (216), the blowing fan (11) is arranged close to one side of the energy collecting plate (21), and the blowing fan (11) obliquely blows to the diffusion area (216) towards one side far away from the energy collecting plate (21).

7. The multi-energy complementary heat storage and pump air conditioning system of claim 2, wherein: the floor heating (3) comprises a radiation plate (31); the radiation plates (31) are respectively paved and installed in the floor and the ceiling of the house; the opposite radiation plates (31) respectively conduct and radiate hot air or cold air to the indoor space; the radiation plate (31) comprises a mounting plate (32); a filling groove (321) is formed in the mounting plate (32); capillary tubes (322) are correspondingly filled in the filling grooves (321); the mounting plates (32) are spliced with each other to form the radiation plate (31), and the capillaries (322) are correspondingly spliced and communicated; the capillary tubes (322) are respectively communicated with the water through pipes for circulation.

8. The multi-energy complementary heat storage and pump air conditioning system of claim 7, wherein: the bottom of the filling groove (321) is rectangular, and the relative top of the filling groove (321) is semicircular; the top of the filling groove (321) is correspondingly arranged in the chamber with the adjusted orientation; an isolation block (33) is fixedly arranged on one side of the capillary tube (322) corresponding to the bottom of the filling groove (321); a heat insulation material is arranged between the isolation block (33) and the bottom of the filling groove (321); the capillary tube (322) and the isolation block (33) are arranged in an integrated structure; a plurality of interlayer layers (331) are arranged in the isolation block (33) at intervals, and the interlayer layers (331) are arranged in a hollow mode; the interlayer layers (331) are isolated by heat resistant blocks (332); the section of the interlayer (331) is arc-shaped, and the interlayer (331) is correspondingly adapted to the bottom of the capillary (322);

the bottom of the isolation block (33) is provided with a vacuum layer (333); the vacuum layer (333) is arranged at a distance from the interlayer, and a heat insulation layer (334) is clamped between the vacuum layer (333) and the interlayer (331); a plurality of vacuum layers are arranged at intervals along the extending direction of the capillary (322); the vacuum layers (333) and the interlayer (331) are arranged in a staggered mode, and the heat resistance block (332) is right opposite to the middle of the vacuum layers (333); the vacuum layer (333) is arranged parallel to the bottom of the filling groove (321).

9. The multi-energy complementary heat storage and pump air conditioning system of claim 8, wherein: the top of the filling groove (321) is provided with a plurality of slotted holes (323); a plurality of bulges (324) are arranged on the side wall of the capillary (322) corresponding to the positions of the slotted holes (323); the protrusions (324) are correspondingly embedded into the slotted holes (323); the cavity (325) inside the protrusion (324) is communicated with the inside of the capillary (322); a plurality of heat conducting rods (326) on the side walls of the bulges (324) are correspondingly inserted into the inner walls of the slotted holes (323).