ITMI20101601A1 - REPLACEMENT SYSTEM WITH ENERGY SAVING FOR BUILDINGS - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION entitled:

ENERGY SAVING SPARE SYSTEM FOR BUILDINGS

The present invention relates in general to a building technology and, in particular, to an innovative technology involving power supply, hot water supply, air conditioning, water saving and fire protection systems for buildings.

The power supply system for buildings is generally derived from the public distribution network at high cost.

The water supply system for buildings is generally derived from solar water heaters, whereby the water is electrically heated by the various users. The disadvantages include that hot water above 90 ° C must be heated by users with high power consumption and water cost.

The flush cistern for buildings uses tap water with a high consumption of water resources. The building air conditioner is used for electric heating and cooling without auxiliary power supply, leading to high energy consumption.

The fire extinguishing system for buildings is required to regularly maintain the pressure of the fire water tank in the upper floor, at the same time the fire pump must often be activated with a complicated procedure.

The main objective of the present invention is to provide an energy-saving replacement system for buildings, where the hot water supply system can supply hot water to the building, the air conditioner allows heating and cooling via a GSHP ( geothermal heat pump), the water saving system allows a tank with a membrane filter to filter the water for the bathroom and domestic water and then send it to the flush cistern on the lower floor. This leads to savings in power and water and also reduces the cost of hot water and air conditioning; in addition, fire water can be obtained from the water tank on the top floor.

The technical solution of the present invention will be described below: an energy-saving replacement system for buildings covers a building, and a power supply system for the building comprises: a cistern in the upper floor, a cistern in the basement, a complex of capillary generators, a solar PV, a downstream load, a water pump and a load of users.

The cistern on the top floor is located on the roof of the building and the cistern in the basement is underground, the water from the cistern on the top floor being supplied to the capillary generator complex; the electricity generated by the complex of capillary generators is supplied to the load of the users, and the electricity generated by the solar PV activates the water pump to transfer water from the tank in the basement to the tank in the upper floor; the load downstream in the public distribution network is supplied to the water pump to transfer water from the tank in the basement to the tank in the upper floor and also to the load of the users.

The capillary generator complex consists of several small hydro-generators whose inlet pipe is connected to the cistern in the upper floor and the outlet pipe is connected to the cistern in the basement.

Said solar PV is arranged laterally on the building where the electricity generated by the solar PV is loaded into the battery and then sent to the water pump to transfer water from the tank in the basement to the tank on the upper floor, while the load downstream in the network distribution system is sent to the water pump at night to transfer water from the cistern in the basement to the cistern on the upper floor.

Said hot water supply system for the building consists of solar water heater, tap water, large hot water tank, and hot water users; some solar water heaters are arranged in the upper part of the cistern in the upper floor and a large hot water tank is arranged in the upper floor to supply hot water to the hot water users.

The solar water heaters are arranged as follows: tap water flows through the parallel solar water heater at level 1, the parallel solar water heater at level 2, ... the water tank of the parallel parallel water heater n in the large hot water tank; the number of the individual solar water heaters in the parallel solar water heater at level 1, in the parallel solar water heater at level 2 ..., in the parallel solar water heater at level n increases to one by one.

Parallel connection of the solar water heaters means that the water tanks of the different solar water heaters are arranged in rows, that there is only one main water inlet and outlet, and that the water tanks of the solar heaters in one row are connected.

A flow rate regulating valve is arranged in the inlet pipe of said solar water heater parallel to level 1.

A drying box is located in the individual rooms of the building, a heating pipe is attached to the drying box, and the hot water in the large hot water tank is connected circularly to the heating pipe.

The water-saving system of the building consists of the downward water pipe in the bathroom, the sewer pipe, the downward pipe for domestic purposes, the membrane filtration tank and the flush cistern.

The flush cistern of the individual rooms on the upper floor is supplied with tap water and the downward water pipe of this cistern is connected to the sewer pipe.

The descending water pipes of the flush cisterns in the individual rooms from the second floor are connected to the sewer pipe, the descending water pipes in the bathrooms and for domestic purposes are connected to the water inlet of the filtration tank a membrane; the filter membrane is fixed in the membrane filtration tank and the outlet pipe of the membrane filtration tank is connected to the water inlet of the flush box in the lower floor; the outflow pipes of the membrane filtration tanks in the individual rooms of the same floor are interconnected.

The descending water pipes of the cisterns in the individual rooms on the first floor and the descending water pipes in the bathrooms or for domestic purposes are connected to the sewer pipe.

Said building air conditioner consists of an underground heat exchange pipe, a GSHP unit, users of the air conditioner and a large hot water tank.

The underground heat exchange pipe is placed underground and connected to the GSHP unit which is in turn connected to the users of the air conditioner, and the piping of the large hot water tank is connected to the heat exchangers of the users of the air conditioner. 'air.

Said fire-fighting system is composed of piping and hoses, the hoses being arranged in the individual rooms and connected to the tank on the upper floor.

The effectiveness of the present invention consists in the fact that:

(1) solar energy can be converted into hydraulic power for the capillary generator complex, then the electrical energy generated by the capillary generator complex is sent to the building's electrical load in a controlled manner; the complex of capillary generators generates power when needed thus saving potential energy of water resources. In the case of insufficient solar energy, the downstream load is used to pump water from the tank in the basement to the tank in the upper floor; as the downstream load price is half the electricity price during the day, this method could provide about 35% lower electricity cost despite the power loss when converting downstream load energy to potential water energy and application through the complex of capillary generators. After the electricity generated by the solar PV has been loaded into the battery, it is sent to the water pump to pump water from the tank in the basement to the tank in the upper floor; since solar energy is not required to be extensively stored in the battery, this avoids a higher storage cost and serious pollution and safety risks when solar energy is extensively stored in the battery. In most cases, the electricity generated by the solar energy and the potential water energy in the high floor cistern are sent to the building's power supply system, with great savings on the cost of power consumption of 30 % approximately.

(2) The water saving system allows a tank with a membrane filter to filter the bathroom water and domestic water and then send it to the flush cistern in the lower floor, thus with great savings of water resources.

(3) The hot water supply system allows you to arrange a parallel solar water heater at level 1, a parallel solar water heater at level 2 ..., a parallel solar water heater at level n in sequence , then heat tap water to feed hot water. The tap water entering the water collection tank of the parallel water heater at level 1 is kept constant, and the heat flow into the water collection tank of the parallel water heater at level 2 is gradually increased so that tap water is quickly heated to obtain hot water; meanwhile, the flow is controlled to regulate the water temperature in the water collection tank of the parallel solar water heater at level n, making hot water available for the users in the building.

(4) The air conditioner could provide heat source from the terrestrial heat and solar energy during the winter season, or chilled air source from the geothermal heat pump and feed them to the premises during the summer season thus saving electric power and cost. heating / cooling. In the winter season, the hot water in the large hot water tank generated by the solar water heater is added to the heat exchanger of the air conditioners, helping to save electricity. In cloudy or rainy weather, the recycle water in the air conditioner is heated by the GSHP unit and pumped to the heat exchanger in the large hot water tank for the building.

(5) The cost for the building of the present invention is 20 - 30% higher than ordinary buildings, but only 2 - 3 years are required for cost savings compared to power / water consumption and air conditioning.

(6) The water from the cistern in the upper floor can be stored for fire control; in the event of any risk of fire in the individual rooms, the water from the cistern on the upper floor is available to ensure timely and safe extinguishing of the fire. This eliminates the inconvenience of regular repair and maintenance of the fire pump.

DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION

Figure 1 is a structural view of the power supply system for the building;

Figure 2 is a structural view of the hot water supply system for the building;

Figure 3 is a view of the configuration of the solar energy heaters of the present invention;

Figure 4 is a structural view of the drying box;

Figure 5 is a structural view of the capillary generator assembly;

figure 6 is a structural view of the small hydrogenerator of figure 4;

Figure 7 is a structural view of the water saving system for the building;

figure 8 is a structural view of the water saving system in the two upper floors;

figure 9 is a structural view of the water saving system in the two lower floors;

Figure 10 is a structural view of the air conditioner for the building.

Referring to Figures 1 - 10, an energy-saving replacement system for buildings covers a building 1 and a power supply system 2 of building 1 and includes: a tank 21 in the upper floor, a tank 22 in the basement, a complex of capillary generators 23, a solar PV 24, a downstream load 25, a water pump 26 and a load of the users 27.

The cistern on the upper floor 21 is located in the roof of the building 1 and the cistern in the basement 22 is placed underground, the water from the cistern on the upper floor 21 being sent to the complex of capillary generators 23; the electrical energy generated by the complex of capillary generators 23 is supplied to the load of the users 27, and the electrical energy generated by the solar PV 24 drives the water pump 26 to transfer water from the tank in the basement 22 to the tank in the upper floor 21 ; the downstream load 25 in the public distribution network is supplied to the water pump 26 to transfer water from the tank in the basement 22 to the tank in the upper floor 21 and also to the load of the users 27.

The capillary generator assembly 23 is composed of some small hydraulic generators 231 of which the inlet pipe 232 is connected to the cistern in the upper floor 21 and the outflow pipe 233 is connected to the cistern in the basement 22.

Said solar PV 24 is arranged laterally on the building where the electrical energy generated by the solar PV 24 is loaded into the battery and then sent to the water pump 26 to transfer water from the tank in the basement 22 to the tank in the upper floor 21, while the downstream load 25 in the public distribution network is sent overnight to the water pump 26 to transfer water from the tank in the basement 22 to the tank in the upper floor 21.

Said hot water supply system 3 for building 1 is composed of: solar water heater 31, tap water 32, large hot water tank 33 and hot water users 34; some solar water heaters 31 are located on the upper part of the upper floor cistern 21 and a large hot water tank 33 is located in the upper floor to supply hot water to the hot water users 34; the solar water heaters are arranged like this: tap water 32 flows through the solar water heater 311 parallel to level 1, the solar water heater 312 parallel to level 2 ..., the water tank of the solar heater water 31n parallel to level n in the large hot water tank 33; the number of the individual solar water heaters in the parallel solar water heater 311 at level 1, in the parallel solar water heater 312 at level 2, ... in the solar water heater 31n at level n increases to one by one; parallel connection of the solar water heaters means that the water tanks of the different solar water heaters 31 are arranged in rows, there is only a single main water inlet and outlet and the water tanks of the solar water heaters 31 in a row are connected.

The inlet pipe of said solar water heater 311 parallel to level 1 is equipped with a flow rate regulating valve 35.

A drying box 36 is located in the individual rooms in building 1, a heating pipe 361 is attached to the drying box 36 and hot water in the large hot water tank 33 is circularly connected to the heating pipe 361.

The water saving system 4 of the building 1 consists of the descending water pipe 41 in the bathroom, the sewer pipe 42, the descending water pipe 43 for domestic purposes, the tank 44 with membrane filtration and from the cistern 45. The cistern 45 of the individual rooms in the upper floor is supplied with tap water and the downpipe of this cistern 45 is connected to the sewer pipe 42.

The descending water pipes of the flush cisterns 45 in the individual rooms from the second floor are connected to the sewer pipe 42, the descending water pipes 41, 43 in the bathrooms and for domestic purposes are connected to the water inlet of the membrane filtration tank 44; the filter membrane is fixed to the membrane filtration tank 44 and the outlet pipe of the membrane filtration tank 44 is connected to the water inlet of the flush box 45 in the lower level. The outflow pipes of the membrane filtration tanks 44 in the individual rooms on the same floor are interconnected.

The descending water pipes of the cisterns 45 in the individual rooms on the first floor, and the descending water pipes 41, 43 in the bathrooms or for domestic purposes are connected to the sewer pipe 42.

Said air conditioner 5 for the building is composed of the underground heat exchange pipe 51, the GSHP unit 52, the air conditioning users 53 and the large hot water tank 33; the heat exchanger tube 51 is located underground and connected to the GSHP unit 52 which is in turn connected to the users of the air conditioner 53, and the piping of the large hot water tank 33 is connected to the heat exchangers 531 of the air conditioning users 53.

Said fire-fighting system for building 1 is composed of piping and hoses, the hoses being arranged in the individual rooms connected to the cistern on the upper floor 21.

Claims (8)

CLAIMS 1. Energy-saving replacement system for buildings covering the building, characterized in that the power supply system for the building comprises: a cistern in the upper floor, a cistern in the basement, a complex of capillary generators, a Solar PV, a load downstream in the public distribution network, a water pump and a load of users; the cistern on the top floor is located on the roof of the building and the cistern in the basement is located underground, the water from the cistern on the top floor being sent to the complex of capillary generators; the electricity generated by the complex of capillary generators is supplied to the load of the users and the electricity generated by the solar PV activates the water pump to transfer water from the tank in the basement to the tank on the upper floor; the load downstream in the public distribution network is supplied to the water pump to transfer water from the tank in the basement to the tank in the upper floor and also to the load of the users; the capillary generator complex is composed of several small hydro-generators whose inlet pipe is connected to the cistern in the upper floor and the outflow pipe is connected to the cistern in the basement. 2. Energy-saving replacement system for buildings according to claim 1, characterized in that said solar PV is arranged laterally on the building, in which the electrical energy generated by the solar PV is charged into the battery and then supplied to the pump of the water to transfer water from the tank in the basement to the tank in the upper floor, while the load downstream in the public distribution network is supplied to the overnight water pump to transfer water from the tank in the basement to the tank in the upper floor. 3. Energy-saving replacement system for buildings according to claim 1, characterized in that said hot water supply system for the building consists of: solar water heater, tap water, large hot water tank and users of hot water; some solar water heaters are arranged in the upper part of the cistern in the upper floor, and a large hot water tank is arranged in the upper floor to supply hot water to the hot water users; the solar water heaters are arranged as follows: tap water flows through the parallel solar water heater at level 1, the parallel solar water heater at level 2, ... the water tank of the solar water heater parallel at level n in the large hot water tank; the number of the individual solar water heaters in the parallel solar water heater at level 1, in the parallel solar water heater at level 2, ... in the parallel solar water heater at level n, increases one by one; Parallel connection of the solar water heaters means that the water tanks of several solar water heaters are arranged in rows, there is only a single main water inlet and outlet and 1 water tanks of the solar water heaters in a row they are connected. 4. Energy-saving replacement system for buildings according to claim 3, characterized in that the inlet pipe of said parallel solar water heater at level 1 is equipped with a flow control valve. 5. Energy-saving replacement system for buildings according to claim 3, characterized in that a drying box is arranged in the individual rooms in the building, a heating pipe is fixed in the drying box, and the hot water in the large hot water tank is connected circularly to the heating pipe. 6. Energy-saving replacement system for buildings according to claim 1, characterized in that the water-saving system of the building consists of the descending water pipe in the bathroom, the sewer pipe, the water pipe water for domestic purposes, from the membrane filtration tank and from the flush cistern, the cistern of the individual rooms in the upper floor is supplied with tap water, and the descending water pipe of this cistern is connected to the sewer pipe; the descending water pipes of the cisterns in the individual rooms from the second floor are connected to the sewer pipe, the descending water pipes in the bathrooms and for domestic purposes are connected to the water inlet of the filtration tank a membrane; the filter membrane is attached to the membrane filtration tank, and the outlet pipe of the membrane filtration tank is connected to the water inlet of the flush box in the lower floor; the outflow pipes of membrane filtration tanks in individual rooms in the same floor are interconnected; the descending water pipes of the cisterns in the individual rooms on the first floor and the descending water pipes in the bathrooms or for domestic purposes are connected to the sewer pipe. 7. Energy saving replacement system for buildings according to claim 1, characterized in that said air conditioner for the building is composed of the underground heat exchange pipe, the GSHP unit, the users of the air conditioner and from the hot water tank; the heat exchanger tube is underground and is connected to the GSHP unit which is in turn connected to the heat exchangers of the users of the air conditioner, and the piping of the large hot water tank is also connected to the heat exchangers of the users of the air conditioner. 8. Energy-saving replacement system for buildings according to claim 1, characterized in that said fire-fighting system is composed of pipes and hoses, the hoses being arranged in the individual rooms and connected to the cistern on the upper floor.