CN114353355B - System of solar energy all-in-one machine using roof in small high-rise residence - Google Patents

Abstract

The application relates to the field of heat supply technology, and discloses a system of a solar energy integrated machine for using a roof in a small high-rise residence, which comprises solar energy, a water supply pipe, a hot water pipe and a water heating pipe, wherein one end of the water supply pipe is communicated with a water source, the other end of the water supply pipe is communicated with an indoor space, and the other end of the hot water pipe is communicated with the solar energy; a pressurizing pump is arranged at the communication position of the water supply pipe and the water source; a first electromagnetic pressure reducing valve is arranged at one side of the communication part of the 1-2F hot water pipe and the water supply pipe, which is far away from the pressurizing pump; a second electromagnetic pressure reducing valve is arranged at one side of the joint of the 3-5F hot water pipe and the water supply pipe, which is close to the pressure pump, and a water inlet pipe is also arranged at 1-5F, and the water inlet pipe is communicated with the room. The application has the effect of effectively solving the problems of larger investment and higher operation and maintenance cost of the solar water heater adopted by the existing small high-rise building.

Description

System of solar energy all-in-one machine using roof in small high-rise residence

Technical Field

The application relates to the field of heat supply technology, in particular to a system of a solar energy integrated machine using a roof in a small high-rise residence.

Background

In the development line of clean renewable energy, solar energy is used to dominate, and the adaptive energy production technology is mature and is widely applied in practice.

In low-rise houses, the solar water heater usually adopts a roof solar integrated machine, and the roof solar integrated machine is quite reliable in the running process and low in maintenance rate, and is popular with vast households. In small high-rise houses, solar water heaters usually adopt balcony wall-mounted or concentrated heat-collecting household water tanks solar water heating systems due to the limitation of conditions such as water pressure and the like.

Aiming at the related technology, the existing solar water heater adopted by a small high-rise has the problems of high investment and high operation and maintenance cost.

Disclosure of Invention

In order to effectively solve the problems of large investment and high operation and maintenance cost of the existing solar water heater adopted by the small high-rise building, the application provides a system of a solar integrated machine using a roof in the small high-rise building.

The application provides a system of a solar energy integrated machine using a roof in a small high-rise residence, which adopts the following technical scheme:

a system of a solar energy integrated machine using a roof in a small high-rise residence comprises solar energy, a water supply pipe, a hot water pipe and a water supply pipe, wherein one end of the water supply pipe is communicated with a water source, the other end of the water supply pipe is communicated with an indoor space, and the other end of the hot water pipe is communicated with the solar energy;

a pressurizing pump is arranged at the communication position of the water supply pipe and the water source;

a first electromagnetic pressure reducing valve is arranged at one side of the communication part of the 1-2F hot water pipe and the water supply pipe, which is far away from the pressurizing pump;

a second electromagnetic pressure reducing valve is arranged at one side of the joint of the 3-5F hot water pipe and the water supply pipe, which is close to the pressure pump, and a water inlet pipe is also arranged at 1-5F, and the water inlet pipe is communicated with the room.

By adopting the technical scheme, the pressurizing pump pressurizes the water supply pipe to supply water, so that the water source can supply solar energy on the top of the residential building along the water supply pipe and the hot water pipe; the water source is pressurized by the booster pump and then is supplied into solar energy by the water supply pipe and the hot water pipe, hot water heated in the solar energy flows into residents by the hot water pipe, and the first electromagnetic pressure reducing valve reduces the pressure of the hot water before the hot water flows into the residents so as to solve the problems that the water pressure is too high and the requirement of entering the residents is not met due to the overlarge floor height difference, and the hot water cannot enter the residents with the 1-2F; when a water source is supplied to solar energy installed on the top of a residential building through a water supply pipe and a hot water pipe, hot water is used by 3-5F residents at the moment, the hot water and the second electromagnetic pressure reducing valve can reduce the water pressure of the water source, and when the residents need hot water, the second electromagnetic pressure reducing valve can reduce the water pressure in the water supply pipe so as to reduce the possibility of bursting of the water supply pipe, and simultaneously, the household pressure of the hot water can be reduced so as to meet the household requirement; the water supply pipe can provide cold water for 1-5F residents, so that daily demands of the residents are met, and cold water for 6F residents and above is provided by the water supply pipe; therefore, the solar energy can be used in small high-rise houses, and the investment and maintenance cost is reduced.

Optionally, the solar energy comprises a water storage tank, a vacuum pipe with one end connected to the water storage tank, a mounting pipe connected to the other end of the vacuum pipe, a sealing sleeve for sealing the vacuum pipe and the water storage tank, and an overflow pipe arranged on the water storage tank, wherein the water supply pipe is communicated with the water storage tank;

the vacuum pipes are arranged at intervals along the axis direction of the water storage tank, one end of each vacuum pipe is an open end, the other end of each vacuum pipe is a closed end, and the open ends of the vacuum pipes are in threaded connection with the water storage tank.

By adopting the technical scheme, the mounting process of the vacuum tube is more convenient and quicker due to the threaded connection of the vacuum tube and the water storage tank, the problem that the original vacuum tube needs to be lubricated during mounting is effectively solved, the mounting operation steps are reduced, and the working efficiency is further effectively improved; the sealing sleeve can reduce the possibility of water leakage at the joint of the vacuum tube and the water storage tank; when water is supplied too much in the water storage tank, the overflow pipe can drain water so as to prevent the possibility of bursting of the water storage tank.

Optionally, a plurality of sleeves matched with the vacuum pipes are arranged on the inner wall of the water storage tank at intervals, and threads matched with the vacuum pipes are formed on the inner wall of the sleeves.

By adopting the technical scheme, the sleeve can strengthen the connection between the water storage tank and the vacuum tube, and strengthen the use strength of the water storage tank and the vacuum tube, thereby effectively prolonging the service life of solar energy; meanwhile, as the solar energy placing position is higher, the water pressure of the water source is too high, and the connection of the sleeve and the vacuum tube also enables the water storage tank to bear larger water pressure, so that the possibility of solar energy damage is reduced.

Optionally, a heater is arranged on the solar energy, the heater comprises a main body and a heating rod arranged at one end of the main body, and the heating rod extends into the water storage tank;

a mounting cover for mounting the heater is arranged outside the heater and is in threaded connection with the sleeve.

By adopting the technical scheme, when the sun appears in a small amount of time, the resident can manually start the heater to electrify the heater, and the heating rod can heat the water in the water storage tank, so that the resident can always use the hot water; the installation cover can protect the main body arranged outside the water storage tank, so that the safety of the heater is enhanced, and the service life of the heater is prolonged.

Optionally, a heating cover is arranged in the water storage tank, one end of the heating cover is provided with an opening, the opening end of the heating cover faces the sleeve, and the heating rod is abutted with the closed end of the heating cover;

the heating cover is made of metal.

Through adopting above-mentioned technical scheme, the heating mantle of metal has good heat conductivity, and heating mantle and heating rod butt can be with the heat transfer on the heating rod to the heating mantle on, then the water in the heating storage water tank to satisfy resident's demand, the heating mantle can protect the heating rod, the security of reinforcing heater.

Optionally, the solar energy further comprises a supporting plate for supporting the vacuum tube, the axis of the supporting plate is perpendicular to the axis of the vacuum tube, and a plurality of clamping grooves matched with the vacuum tube are formed in the end face of the supporting plate at intervals.

By adopting the technical scheme, the vacuum tube is required to bear larger pressure due to the weight of water and the action of water pressure, so that the supporting plate can further enhance the supporting force of the solar frame body on the vacuum tube, further enhance the use strength of the vacuum tube and prolong the service life of the vacuum tube.

Optionally, a protective cloth is arranged on the periphery of the water storage tank, the protective cloth is consistent with the peripheral surface of the water storage tank in size, a connecting belt is arranged on one side of the protective cloth, and a buckle matched with the connecting belt is arranged on the other side of the protective cloth.

By adopting the technical scheme, the protective cloth can insulate the water storage tank, so that the heat loss of hot water in the water storage tank is reduced, and the water consumption of residents is more convenient; the connecting belt and the buckle are more convenient for the staff to replace and clean the protective cloth.

Optionally, waterproof cloth is sewn on the outer cloth surface of the protective cloth.

Through adopting above-mentioned technical scheme, when weather such as sleet, the waterproof cloth can reduce the rainwater to the corruption of storage water tank, reduces bad weather to the influence of storage water tank, prolongs solar energy's life.

Optionally, a rust inhibitive paint is coated on the peripheral wall of the heating mantle.

In summary, the present application includes at least one of the following beneficial technical effects:

the solar water supply pipe, the hot water pipe and the indoor water supply pipe are arranged, so that the solar water supply pipe can meet the requirement of using solar energy in small high-rise and effectively reduce the investment cost;

by arranging the water storage tank, the vacuum pipe, the mounting pipe, the sealing sleeve and the overflow pipe, the mounting operation steps can be reduced, and the working efficiency is further effectively improved;

through setting up a plurality of sleeve pipes that are provided with the vacuum tube adaptation on the inner wall of storage water tank interval, can strengthen the connection of storage water tank and vacuum tube, reinforcing storage water tank and vacuum. The service strength of the pipe is further improved, and the service life of solar energy is further effectively prolonged.

Drawings

FIG. 1 is a schematic diagram of a system of a 1-2F solar all-in-one machine.

FIG. 2 is a schematic diagram of a system of a 3-5F solar all-in-one machine.

Fig. 3 is a schematic diagram of a system of the solar energy all-in-one machine of 6F and above.

Fig. 4 is a schematic view of the structure of solar energy.

Fig. 5 is a schematic view of a partial structure of solar energy.

Fig. 6 is a schematic partial structure of the protective cloth.

Reference numerals illustrate: 1. a hot water pipe; 11. a first electromagnetic pressure reducing valve; 2. a water supply pipe; 21. a pressurizing pump; 22. a second electromagnetic pressure reducing valve; 3. a water supply pipe; 4. solar energy; 41. a water storage tank; 411. a sleeve; 412. a heating mantle; 413. an inductor; 42. a vacuum tube; 43. installing a pipe; 431. a mounting hole; 44. sealing sleeve; 45. an overflow pipe; 46. a heater; 461. a main body; 462. a heating rod; 47. a mounting cover; 48. a support plate; 481. a clamping groove; 49. a frame body; 5. a protective cloth; 51. a connecting belt; 52. a buckle; 6. a tubing well; 7. a residence.

Detailed Description

The present application will be described in further detail with reference to fig. 1-6.

The embodiment of the application discloses a system of a solar energy integrated machine using a roof in a small high-rise residence.

Referring to fig. 1, a system of a solar energy integrated machine using a roof in a small high-rise building includes solar energy 4, a water supply pipe 2 communicating with the solar energy 4, a hot water pipe 1 communicating with the water supply pipe 2, and a water supply pipe 3 communicating with an indoor space. One end of the water supply pipe 2 far away from the solar energy 4 is communicated with an external water source.

Referring to fig. 1, a pressurizing pump 21 is arranged at the communication position of a water supply pipe 2 and an external water source, the communication position of the 1-2F water supply pipe 2 and a hot water pipe 1 is positioned in a pipeline well 6, a first electromagnetic pressure reducing valve 11 is arranged at one side, far away from the pressurizing pump 21, of the communication position of the hot water pipe 1 and the water supply pipe 2 in the pipeline well 6, and the pressure behind the first electromagnetic pressure reducing valve 11 is 0.2MPa. The other end of the water supply pipe 2 is communicated with the room. When the solar energy 4 needs to be supplied with water, the pressurizing pump 21 pressurizes the solar energy 4 to supply water under pressure, when residents need to use hot water, the hot water flows into residents' homes of 1-2F along the hot water pipe 1 by the solar energy 4, at the moment, the first electromagnetic pressure reducing valve 11 is started, and the first electromagnetic pressure reducing valve 11 decompresses the hot water, so that the hot water meets the requirement of entering the residents.

Referring to fig. 2, a 3-5F hot water pipe 1 is directly connected into a resident's home, a second electromagnetic pressure reducing valve 22 is arranged on one side of the hot water pipe 1, which is close to a pressure pump 21, at the position where the hot water pipe 1 is communicated with a water supply pipe 2, and the pressure behind the first electromagnetic pressure reducing valve 11 is 0.34MPa. When the solar energy 4 is supplying water, if the user of 3-5F is using hot water, the second electromagnetic pressure reducing valve 22 can reduce the water pressure in the water supply pipe 2, so as to reduce the situation that the water supply pipe 2 is cracked, and improve the safety of the water supply pipe 2.

With reference to fig. 1 and 2, a water inlet pipe is further provided at 1-5F, one end of which is connected to municipal water supply, and the other end is connected to the resident's home to supply cold water to the resident.

Referring to fig. 3, in a resident's home of 6F and above, the water supply pipe 2 can supply hot water to the resident at the same time as cold water. Therefore, small and high-rise households can be suitable for the solar integrated machine, and investment cost and maintenance cost are further reduced.

Referring to fig. 4 and 5, the solar energy 4 includes a frame 49, a water storage tank 41 mounted on the frame 49, a vacuum tube 42 having one end communicating with the water storage tank 41, a mounting tube 43 connected to the other end of the vacuum tube 42, a sealing sleeve 44 for sealing the vacuum tube 42 and the water storage tank 41, a heater 46 provided on the solar energy 4, and a support plate 48 for supporting the vacuum tube 42, wherein one end of the vacuum tube 42 is an open end, the other end is not a closed end, and a screw thread is provided on an outer wall of the open end of the vacuum tube 42.

A plurality of through holes for installing the vacuum pipes 42 are arranged on the wall of the water storage tank 41 at intervals along the axial direction of the water storage tank 41, a plurality of sleeves 411 corresponding to the through holes one by one are fixedly connected in the water storage tank 41, the axis of each sleeve 411 is collinear with the circle center of the through hole, and threads matched with the vacuum pipes 42 are formed on the inner wall of each sleeve 411 in a machining mode.

Referring to fig. 4 and 5, both ends of the mounting tube 43 are fixedly mounted on the frame 49, respectively, a straight line along which the length direction of the mounting tube 43 is located is parallel to the axis of the water storage tank 41, and a plurality of mounting holes 431 are provided on the peripheral wall of the mounting tube 43 at intervals along the length direction of the mounting tube 43, and the mounting holes 431 are in one-to-one correspondence with the vacuum tubes 42.

Before use, the sealing sleeve 44 is sleeved on the vacuum tube 42, when in use, the vacuum tube 42 is screwed, the vacuum tube 42 is matched with the sleeve 411, then the closed end of the vacuum tube 42 is inserted into the mounting tube 43, the vacuum tube 42 is screwed again, the vacuum tube 42 is matched with the mounting tube 43, then the sealing sleeve 44 is moved to the joint of the vacuum tube 42 and the water storage tank 41, and the space between the vacuum tube 42 and the water storage tank 41 is sealed. The threaded connection makes the connection between the vacuum tube 42 and the water storage tank 41 more stable, and the sleeve 411 makes the connection between the vacuum tube 42 and the water storage tank 41 more stable, and prolongs the service life of the solar energy 4.

Referring to fig. 4 and 5, the heaters 46 are provided in two, and the two heaters 46 are respectively mounted on the water storage tank 41 at both sides of the vacuum tube 42, the heaters 46 include a main body 461, and a heating rod 462 mounted on the main body 461, the heating rod 462 is L-shaped, one end of the heating rod 462 is connected to the main body 461, and the other end is suspended.

A heating cover 412 is arranged in the water storage tank 41, the heating cover 412 is matched with the heating rod 462, the heating cover 412 is cylindrical, one end of the heating cover 412 is a closed end, the other end is an open end, the open end of the heating cover 412 faces the sleeve 411, and the inner diameter of the heating cover 412 is larger than or equal to the outer cover of the sleeve 411.

Referring to fig. 4 and 5, a mounting cover 47 is further provided outside the heater 46, the mounting cover 47 is adapted to the main body 461, the mounting cover 47 includes an upper cover and a lower cover, the upper cover is tubular, the lower cover is tubular, one end of the lower cover has an opening, the other end is a closed end, the main body 461 is adapted to the lower cover, and the open end of the lower cover is communicated with the upper cover. Threads which are matched with the sleeve 411 are formed on the outer wall of the upper cover.

In use, the main body 461 is mounted in the lower housing of the mounting housing 47, then the heating rod 462 is mounted in the water storage tank 41 through the sleeve 411, one end of the heating rod 462 is abutted against the inner wall of the heating housing 412, and then the mounting housing 47 is screwed, and the heater 46 is mounted on the solar energy 4 with the upper housing of the mounting housing 47 engaged with the screw threads of the sleeve 411. The heating cover 412 is made of metal, so that the heating cover 412 has good thermal conductivity, the heating cover 412 can enlarge the heat dissipation area of the heat collector bar, and the heating rate can be improved; meanwhile, the heating cover 412 can protect the heating rod 462, after long-time use, scales can damage the heating rod 462, the heating cover 412 can protect the heating rod 462, the service life of the heating rod 462 is prolonged, and the safety of the solar energy 4 is enhanced. The outer wall of the heating cover 412 is further coated with an anti-rust paint, which can prevent scale from being generated on the heating cover 412, so that the heat dissipation effect of the heating cover 412 is ensured.

Referring to fig. 4 and 5, the mounting cover 47 protects the main body 461, reduces the influence of damage to the heater 46 due to wind and rain, and prolongs the service life of the heater 46. When the resident encounters a thunderstorm or other weather, the resident can manually open the heat collector, so that the heater 46 heats the water in the water storage tank 41, and further, the hot water supply of the resident is ensured. The installation cover 47 is the heating cover 412 that adopts insulating material to make, because the heater 46 needs to be circular telegram with the external world, consequently the heating cover 412 can effectively reduce the occurrence of the inconvenient circumstances of dismantling of staff, and then protects staff and resident's safety, reinforcing solar energy 4's security.

An overflow pipe 45 is further arranged on the water storage tank 41, the overflow pipe 45 is arranged on the side wall of the water storage tank 41 at a position far away from the sleeve 411, and when the water in the water storage tank 41 is excessive, the excessive water overflows from the overflow pipe 45 to protect the water storage tank 41.

Referring to fig. 4 and 5, the solar energy 4 further includes a support plate 48, two ends of the support plate 48 are respectively and fixedly connected to the frame 49, a straight line in the length direction of the support plate 48 is perpendicular to a straight line in the length direction of the vacuum tube 42, a plurality of clamping grooves 481 are spaced apart along the length direction of the support plate 48 on the plate surface of the support plate 48, and the clamping grooves 481 are adapted to the vacuum tube 42. Since the intermediate position of the vacuum tube 42 is in a suspended state, the support plate 48 can support the suspended portion of the vacuum tube 42, enhancing the safety of the vacuum tube 42 and thus the safety of the solar energy 4.

A rubber pad (not shown) is further provided on the inner wall of the clamping groove 481, and the rubber pad can strengthen the friction between the vacuum tube 42 and the support plate 48, thereby strengthening the safety of the vacuum tube 42.

Referring to fig. 6, a protective cloth 5 is further provided outside the water storage tank 41, the protective cloth 5 is adapted to the water storage tank 41, a connecting band 51 is sewn on one side of the protective cloth 5, a buckle 52 adapted to the connecting band 51 is sewn on the other side of the protective cloth 5, and when in use, the protective cloth 5 wraps the water storage tank 41 inside, and then the connecting band 51 is clamped on the buckle 52, so that the protective cloth 5 is fixed. The waterproof cloth is sewn on the outer cloth surface of the protective cloth 5, so that the waterproof cloth can reduce the corrosion of rainwater to the water storage tank 41, reduce the influence of severe weather to the water storage tank 41 and prolong the service life of the solar energy 4 in the weather such as rain and snow; meanwhile, the protection cloth 5 can insulate the water storage tank 41, and heat loss of the water storage tank 41 is reduced.

The implementation principle of the system of the solar integrated machine using the roof in the small high-rise residence provided by the embodiment of the application is as follows: the solar energy 4 is supplied with water through the water supply pipe 2 and the hot water pipe 1, and the hot water generated by the solar energy 4 can enter the resident's home through the water supply pipe 2 and the hot water pipe 1 at the same time. Under the action of the first electromagnetic pressure reducing valve 11 and the second electromagnetic pressure reducing valve 22, the household water pressure of the hot water can meet the standard, and further meet the use requirements of residents.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (3)

1. A system of solar energy all-in-one machine using roofing in small high-rise houses, characterized in that: the solar water heater comprises solar energy (4), a water supply pipe (2) with one end communicated with a water source and the other end communicated with the room, and a hot water pipe (1) with one end communicated with the water supply pipe (2) and the other end communicated with the solar energy (4);

a pressurizing pump (21) is arranged at the communication position of the water supply pipe (2) and the water source;

a first electromagnetic pressure reducing valve (11) is arranged at one side of the communication part of the 1-2F hot water pipe (1) and the water supply pipe (2) far away from the pressurizing pump (21);

a second electromagnetic pressure reducing valve (22) is arranged at one side of the communication part of the 3-5F hot water pipe (1) and the water supply pipe (2) close to the pressurizing pump (21), a water inlet pipe is also arranged at 1-5F, and the water inlet pipe is communicated with the room;

the solar energy (4) comprises a water storage tank (41), a vacuum tube (42) with one end connected to the water storage tank (41), a mounting tube (43) connected to the other end of the vacuum tube (42), a sealing sleeve (44) for sealing the vacuum tube (42) and the water storage tank (41), and an overflow tube (45) arranged on the water storage tank (41), wherein the water supply tube (2) is communicated with the water storage tank (41);

the plurality of vacuum pipes (42) are arranged at intervals along the axis direction of the water storage tank (41), one end of each vacuum pipe (42) is an open end, the other end is a closed end, and the open end of each vacuum pipe (42) is in threaded connection with the water storage tank (41);

a heater (46) is arranged on the solar energy (4), the heater (46) comprises a main body (461) and a heating rod (462) arranged at one end of the main body (461), and the heating rod (462) extends into the water storage tank (41);

a plurality of sleeves (411) matched with the vacuum pipes (42) are arranged on the inner wall of the water storage tank (41) at intervals, and threads matched with the vacuum pipes (42) are formed on the inner wall of the sleeves (411);

a mounting cover (47) for mounting the heater (46) is arranged outside the heater (46), and the mounting cover (47) is in threaded connection with the sleeve (411); the mounting cover (47) comprises an upper cover and a lower cover, the upper cover is tubular, the lower cover is tubular, one end of the lower cover is provided with an opening, the other end of the lower cover is a closed section, the main body (461) is matched with the lower cover, the open end of the lower cover is communicated with the upper cover, and threads matched with the sleeve (411) are formed on the outer wall of the upper cover in a machining mode;

a heating cover (412) is arranged in the water storage tank (41), one end of the heating cover (412) is provided with an opening, the opening end of the heating cover (412) faces the sleeve (411), and the heating rod (462) is abutted with the closed end of the heating cover (412); the heating cover (412) is made of metal;

the periphery of the water storage tank (41) is provided with a protective cloth (5), the protective cloth (5) is consistent with the periphery of the water storage tank (41), one side of the protective cloth (5) is provided with a connecting belt (51), and the other side of the protective cloth (5) is provided with a buckle (52) matched with the connecting belt (51); the waterproof cloth is sewed on the outer cloth surface of the protective cloth (5).

2. A system of solar energy integrated machines for use with roofing in small high-rise homes according to claim 1, wherein: the solar energy (4) further comprises a supporting plate (48) for supporting the vacuum tube (42), the axis of the supporting plate (48) is perpendicular to the axis of the vacuum tube (42), and a plurality of clamping grooves (481) matched with the vacuum tube (42) are formed on the end face of the supporting plate (48) at intervals.

3. A system of solar energy integrated machines for use with roofing in small high-rise homes according to claim 1, wherein: a rust inhibitive paint is coated on the peripheral wall of the heating mantle (412).