CN115060035B

CN115060035B - Heat-accumulating type heat recovery type modularized air-cooled hot water unit capable of running at low temperature

Info

Publication number: CN115060035B
Application number: CN202210562286.7A
Authority: CN
Inventors: 夏林; 夏晓宏; 肖靖东
Original assignee: Baosteel Air Conditioning Taizhou Co ltd
Current assignee: Baosteel Air Conditioning Taizhou Co ltd
Priority date: 2022-05-23
Filing date: 2022-05-23
Publication date: 2023-07-21
Anticipated expiration: 2042-05-23
Also published as: CN115060035A

Abstract

The invention discloses a heat-accumulating type and low-temperature-operation heat recovery type modularized air-cooling and water-heating unit, which belongs to the technical field of air-cooling and water-heating units, wherein equipment is placed outdoors and fixedly installed outdoors in a penetrating manner, when moving, a buffering cross, an end hinged sliding block, an end fixed plate frame and a wall sliding rail are mutually matched to perform moving buffering, a double-head motor is started to adjust a horizontal adjusting screw rod to rotate, a horizontal adjusting plate is adjusted by the horizontal adjusting screw rod to drive a supporting plate to adjust the distance, an arc-shaped solar plate is driven by a starting end fixed plate frame adjusting seat to perform azimuth rotation adjustment, reflected light of the arc-shaped solar plate irradiates the outer side of a cooling bin, the reflected light irradiates the cooling bin in winter and irradiates an air duct to perform heat preservation on the inner spiral cooling pipe in penetrating through the cooling bin, and in summer, the inner spiral cooling pipe is led into a winding pipe through cold water, and the winding pipe is wound on the outer side of the air duct to perform cooling and heat exchange treatment on inner spiral cooling pipe hot water inside the air duct.

Description

Heat-accumulating type heat recovery type modularized air-cooled hot water unit capable of running at low temperature

Technical Field

The invention relates to an air-cooled hot water unit, in particular to a heat-recovery type modularized air-cooled hot water unit which can perform heat accumulation and can operate at low temperature, and belongs to the technical field of air-cooled hot water units.

Background

The air-cooled heat pump unit is a circulation system formed from compressor-heat exchanger-throttle-heat absorber-compressor, etc. the refrigerant can be circularly flowed in the system under the action of compressor, and can be used for implementing the process of raising pressure and raising temperature of gas state (temp. up to 100 deg.C), making it be fed into heat exchanger, making it undergo the process of heat exchange with wind, cooling and converting it into liquid state, when it is run into heat absorber, the liquid state can be quickly absorbed and evaporated, and converted into gas state again, at the same time the temperature can be reduced to 20-30 deg.C, at the same time the air around the heat absorber can continuously transfer low-temp. heat to refrigerant, and the refrigerant can be continuously circulated so as to implement the process of converting low-temp. heat in the air into high-temp. heat and heating cold water.

The air-cooled hot water unit in the prior approximation has the following problems:

1. in the prior art, an air-cooled hot water unit arranged outdoors cannot realize a good function of collecting external new energy, so that energy is wasted;

2. the air-cooled hot water unit in the prior art cannot well utilize energy generated by rainwater;

3. the air-cooled hot water unit in the prior art cannot realize the adjusting function and has single function;

therefore, the heat recovery type modularized air-cooled hot water unit which can be operated at low temperature is designed to solve the problems.

Disclosure of Invention

The invention mainly aims to provide a heat-recovery type modularized air-cooled hot water unit capable of running at a low temperature, which is characterized in that equipment is placed outdoors and fixedly installed outdoors in a penetrating manner, when the equipment moves, the equipment is moved and buffered through the mutual coordination of a buffering cross, an end hinged sliding block, an end fixed plate frame and a wall sliding rail, a double-headed motor is started to adjust the rotation of a horizontal adjusting screw rod, the horizontal adjusting screw rod is adjusted to drive a supporting plate to adjust the distance, an arc-shaped solar plate is driven to rotate and adjust by the adjusting seat of the starting end fixed plate frame, reflected light of the arc-shaped solar plate irradiates the outer side of a cooling bin, the reflected light irradiates the cooling bin in winter and irradiates the cooling bin in a wind guide tube to keep the temperature of an inner spiral cooling tube, cold water is guided into a winding tube in summer, the winding tube winds the outer side of the wind guide tube in the wind guide tube to cool and exchanges heat with the inner spiral cooling tube hot water in the wind guide tube, and rain water is guided into the inner guide tube through the arc-shaped liquid guide seat and the arc-shaped solar plate in the rain day, the rain water and the outer side of the wind guide tube drives the arc-shaped solar plate to rotate and the power generator to rotate and adjust the outer side of a power generation drum to drive the arc-shaped solar plate to rotate and adjust the power generator to drive the wind generator to enter the wind guide tube to the wind guide fan to cool through the wind to the wind and enter the wind guide tube to the wind and pass through the wind guide tube.

The aim of the invention can be achieved by adopting the following technical scheme:

the utility model provides a heat accumulation formula and can low temperature operation's heat recovery type modularization forced air cooling hot water unit, includes the base, the side slide rail is installed to the both sides at base top, the outside both ends cover of side slide rail is equipped with can be in gliding horizontal adjustment board on the side slide rail, the top of horizontal adjustment board is equipped with the buffer frame subassembly, the backup pad is installed at the top of buffer frame subassembly, the arc liquid guide seat is installed at the top of backup pad, just the top mid-section department of arc liquid guide seat installs angle regulation subassembly, installs arc solar panel on this angle regulation subassembly, the top mid-section department of base installs can drive horizontal adjustment subassembly of horizontal adjustment board, U type frame is installed to both sides department in the top of base, the interior mid-section department of U type frame installs hydroelectric power generation subassembly, and hydroelectric power generation subassembly with arc liquid guide seat and arc solar panel mutually support, the top of liquid guide plate installs the cooling storehouse, the inside of cooling storehouse is equipped with water cooling subassembly, cooling storehouse both ends intercommunication wind cooling subassembly.

Preferably, the buffer frame assembly comprises wall slide rails, end hinged sliding blocks, buffer cross frames and end fixing plate frames, wherein the top of the horizontal adjusting plate and the bottom of the supporting plate are provided with the wall slide rails, the outer side of each wall slide rail is sleeved with the corresponding end hinged sliding block, the buffer cross frames are hinged between the end hinged sliding blocks, and the end fixing plate frames are hinged between the buffer cross frames.

Preferably, the angle adjusting component comprises a side hinging seat, an adjusting seat and an adjusting motor, wherein the side hinging seat is arranged at the side middle part of the arc-shaped liquid guide seat, the adjusting motor is arranged at the top of one side of the side hinging seat, the output end of the adjusting motor penetrates through the side hinging seat to be provided with the adjusting seat, and the arc-shaped solar panel is arranged at the outer end part of the adjusting seat.

Preferably, the horizontal adjusting assembly comprises a double-headed motor and a horizontal adjusting screw rod, the double-headed motor is installed at the top middle part of the base, the horizontal adjusting screw rods are installed at two output ends of the double-headed motor, and the horizontal adjusting screw rods penetrate through the horizontal adjusting plate and are meshed with the horizontal adjusting plate.

Preferably, the hydroelectric power generation assembly comprises a generator, a liquid guide inner frame, a connecting rotating rod and a power generation roller, wherein the liquid guide inner frame is arranged at the middle part of the inner side of the U-shaped frame, the generator is arranged at two ends of one side of the liquid guide inner frame, the output end of the generator penetrates through the liquid guide inner frame to be provided with the connecting rotating rod, and the power generation roller is sleeved on the outer side of the connecting rotating rod.

Preferably, the water cooling assembly comprises an end fixing plate frame, an air duct, an internal spiral cooling pipe and a winding pipe, wherein the end fixing plate frame is arranged at two ends of the inside of the air duct, and the air duct is arranged in the end fixing plate frame.

Preferably, an internal spiral cooling pipe is arranged in the air duct, two ends of the internal spiral cooling pipe penetrate through the air duct and the cooling bin, a winding pipe is wound on the outer side of the air duct, and two ends of the winding pipe penetrate through the cooling bin

Preferably, the wind cooling assembly comprises a fan, an end fan bin and a wind scooper, wherein the end fan bin is arranged at two ends of the cooling bin, the fan is arranged in the end fan bin, and the wind scooper is communicated with the outer side of the end fan bin.

Preferably, the air-cooled hot water unit further comprises the following using method:

step one: the equipment is placed outdoors and fixedly installed outdoors through the equipment;

step two: when moving, the cross frame, the end hinged sliding blocks, the end fixed plate frame and the wall sliding rail are matched with each other to perform moving buffering;

step three: starting the double-headed motor to adjust the horizontal adjusting screw to rotate, and adjusting the horizontal adjusting plate to drive the supporting plate to adjust the distance through the horizontal adjusting screw;

step four: the adjusting seat is adjusted by the starting end fixing plate frame to drive the arc-shaped solar panel to perform azimuth rotation adjustment, so that reflected light of the arc-shaped solar panel irradiates the outer side of the cooling bin;

step five: the internal spiral cooling tube is insulated by reflecting light and irradiating on the cooling bin and penetrating through the cooling bin and irradiating on the air duct in winter;

step six: in summer, cold water is led into the winding pipe, and the winding pipe is wound on the outer side of the air duct to cool and heat exchange hot water of the internal spiral cooling pipe in the air duct;

step seven: in rainy days, rainwater is guided into the inner liquid guide frame through the arc-shaped liquid guide seat and the arc-shaped solar panel, so that the rainwater collides with the outer side edge of the power generation roller to drive the power generation roller to rotate so as to regulate the power generator to generate power;

step eight: the fan is started to lead the wind to the fan through the wind scooper and enter the wind guide barrel through the fan to penetrate the wind guide barrel to cool the inner spiral cooling pipe.

The beneficial technical effects of the invention are as follows:

according to the heat recovery type modularized air-cooled hot water unit capable of accumulating and running at low temperature, equipment is placed outdoors and fixedly installed outdoors in a penetrating manner, when moving, moving buffering is carried out through mutual matching of a buffering cross, an end hinged sliding block, an end fixed plate frame and a wall sliding rail, a double-headed motor is started to adjust a horizontal adjusting screw rod to rotate, a horizontal adjusting plate is adjusted through the horizontal adjusting screw rod to drive a supporting plate to adjust the distance, an arc-shaped solar plate is driven by a starting end fixed plate frame adjusting seat to carry out azimuth rotation adjustment, reflected light of the arc-shaped solar plate irradiates on the outer side of a cooling bin, light reflected irradiates on the cooling bin in winter and irradiates on an air duct through the cooling bin to keep temperature of an inner spiral cooling tube, cold water is led into a winding tube in summer, the winding tube is wound on the outer side of the air duct to cool and heat exchange treatment is carried out on the inner spiral cooling tube hot water inside the air duct, and in rainy days, rainwater is led into the inner air duct through an arc-shaped liquid guide seat and an arc-shaped solar plate to drive a supporting plate to carry out interval adjustment through the horizontal adjusting screw, the rainwater and the outer side edge of the drum to drive a power generation drum to rotate and adjust the power generation drum to drive the power generation drum to carry out azimuth adjustment, and the power generation device to pass through the air duct to enter the air duct into the air duct to cool the air duct to carry out power generation treatment.

Drawings

FIG. 1 is a schematic view of a first perspective view of the overall structure of a device of a preferred embodiment of a regenerative and cryogenically operable modular air-cooled hot-water unit according to the present invention;

FIG. 2 is a schematic view of a second perspective view of the entire apparatus of a preferred embodiment of a regenerative and cryogenically operable modular wind-cooled hot-water unit according to the present invention;

FIG. 3 is a perspective view of a third perspective view of the entire apparatus of a preferred embodiment of a regenerative and cryogenically operable modular wind-cooled hot-water unit according to the present invention;

FIG. 4 is a perspective view of a fourth perspective view of the entire apparatus of a preferred embodiment of a regenerative and cryogenically operable modular wind-cooled hot-water unit according to the present invention;

FIG. 5 is an enlarged view of the structure at a of a preferred embodiment of a regenerative and cryogenically operable modular air-cooled hot water unit according to the present invention;

FIG. 6 is a schematic view of a buffer cross assembly of a preferred embodiment of a regenerative and cryogenically operable modular air-cooled hot water unit according to the present invention;

FIG. 7 is a schematic diagram of a cooling tube assembly and air cooling assembly combination structure of a preferred embodiment of a regenerative and low-temperature operable heat recovery type modular air cooling and heating water unit according to the present invention;

FIG. 8 is a schematic perspective view of a horizontal adjusting rack assembly, a buffer rack assembly and a water power generation assembly of a preferred embodiment of a regenerative and cryogenically operable modular wind-cooled hot-water unit according to the present invention;

FIG. 9 is a schematic perspective view of a water power generation assembly of a preferred embodiment of a regenerative and cryogenically operable modular wind-cooled hot-water unit according to the present invention;

fig. 10 is a schematic perspective view showing a combination structure of a horizontal adjusting rack assembly and a buffer rack assembly of a preferred embodiment of a regenerative and low-temperature-operation heat recovery type modular air-cooled hot water unit according to the present invention.

In the figure: the device comprises a 1-base, a 2-side sliding rail, a 3-horizontal adjusting plate, a 4-supporting plate, a 5-arc liquid guide seat, a 6-horizontal adjusting screw, a 7-generator, an 8-U-shaped frame, a 9-end hinged sliding block, an 11-buffering cross frame, a 12-liquid guide plate, a 13-arc solar panel, a 14-cooling bin, a 15-end fan bin, a 16-air guide cover, a 17-liquid guide inner frame, a 18-generating roller, a 19-side hinged seat, a 20-double-headed motor, a 21-fan, a 22-adjusting seat, a 23-adjusting motor, a 24-end fixed plate frame, a 25-air guide cylinder, a 26-internal spiral cooling pipe, a 27-winding pipe and a 28-wall sliding rail.

Detailed Description

In order to make the technical solution of the present invention more clear and obvious to those skilled in the art, the present invention will be described in further detail with reference to examples and drawings, but the embodiments of the present invention are not limited thereto.

As shown in fig. 1-10, the heat-storage type modularized air-cooling and water-heating unit capable of running at low temperature provided by this embodiment comprises a base 1, side sliding rails 2 are installed on two sides of the top of the base 1, horizontal adjusting plates 3 capable of sliding on the side sliding rails 2 are sleeved at two ends of the outer sides of the side sliding rails 2, buffer frame components are arranged at the tops of the horizontal adjusting plates 3, supporting plates 4 are installed at the tops of the buffer frame components, arc-shaped liquid guide seats 5 are installed at the tops of the supporting plates 4, angle adjusting components are installed at the top middle parts of the arc-shaped liquid guide seats 5, arc-shaped solar panels 13 are installed on the angle adjusting components, horizontal adjusting components capable of driving the horizontal adjusting plates 3 are installed at the top middle parts of the base 1, hydraulic power generating components are installed at the inner middle parts of U-shaped frames 8,U of the top middle sides of the base 1, the hydraulic power generating components are mutually matched with the arc-shaped liquid guide seats 5 and the arc-shaped solar panels 13, liquid guide plates 12 are installed at the tops of the U-shaped frames 8, cooling bins 14 are installed at the tops of the liquid guide plates 12, cooling bins 14 are installed at the tops of the cooling bins 14, and cooling components are arranged at the inner sides of the cooling bins 14, and the cooling components are communicated with cooling wind components at the two ends.

The device is placed outdoors and fixedly installed outdoors in a penetrating manner, when moving, the device moves and buffers through the mutual matching of the buffering cross 11, the end hinged sliding block 9, the end fixed plate frame 24 and the wall sliding rail 28, the double-headed motor 20 is started to adjust the rotation of the horizontal adjusting screw rod 6, the horizontal adjusting plate 3 is adjusted to drive the supporting plate 4 to adjust the distance, the starting end fixed plate frame 24 is adjusted to adjust the adjusting seat 22 to drive the arc-shaped solar panel 13 to conduct azimuth rotation adjustment, reflected light of the arc-shaped solar panel 13 irradiates the outer side of the cooling bin 14, reflected light irradiates the cooling bin 14 in winter and irradiates the cooling bin 14 to heat the inner spiral cooling tube 26 in the air duct 25, cold water is guided into the winding tube 27 in summer, the winding tube 27 winds the outer side of the air duct 25 to conduct cooling heat exchange treatment to the inner spiral cooling tube 26 in the air duct 25, and in the rainy days, the rainwater is guided into the air duct 17 through the arc-shaped liquid guide seat 5 and the arc-shaped solar panel 13, the rainwater and the outer side edge of the power generation drum 18 are impacted to drive the power generation drum 7 to rotate to drive the power generation drum 18 to rotate the power generator 21 to the air duct 21 to enable the power generation drum 21 to enter the air duct 25 to the air duct 25, and the air duct 21 to penetrate the air duct 25 to enable the cooling tube 21 to enter the air duct 25 to the cooling treatment.

In this embodiment, the buffer rack assembly includes wall slide rails 28, end hinge slide blocks 9, buffer cross frames 11 and end fixing plate frames 24, the top of the horizontal adjusting plate 3 and the bottom of the supporting plate 4 are both provided with the wall slide rails 28, the outer sides of the wall slide rails 28 are sleeved with the end hinge slide blocks 9, the end hinge slide blocks 9 are hinged with the buffer cross frames 11, and the end fixing plate frames 24 are hinged between the buffer cross frames 11.

In this embodiment, the angle adjusting assembly includes a side hinge seat 19, an adjusting seat 22 and an adjusting motor 23, the side hinge seat 19 is installed at the side middle part of the arc-shaped liquid guiding seat 5, the adjusting motor 23 is installed at the top of one side of the side hinge seat 19, the adjusting seat 22 is installed through the side hinge seat 19 at the output end of the adjusting motor 23, and the arc-shaped solar panel 13 is installed at the outer end part of the adjusting seat 22.

In this embodiment, the horizontal adjusting assembly includes a double-headed motor 20 and a horizontal adjusting screw 6, the double-headed motor 20 is installed at the top middle part of the base 1, the horizontal adjusting screw 6 is installed at two output ends of the double-headed motor 20, and the horizontal adjusting screw 6 penetrates through the horizontal adjusting plate 3 and is meshed with the horizontal adjusting plate 3.

In this embodiment, the hydroelectric power generation assembly includes generator 7, liquid guiding inner frame 17, connection bull stick and power generation cylinder 18, and liquid guiding inner frame 17 is installed to the inboard middle part department of U type frame 8, and generator 7 is installed at one side both ends of liquid guiding inner frame 17, and the connection bull stick is installed in the output of generator 7 running through liquid guiding inner frame 17, and the outside cover of connection bull stick is equipped with power generation cylinder 18.

In this embodiment, the water cooling assembly includes an end fixing plate frame 24, an air duct 25, an internal spiral cooling tube 26 and a winding tube 27, the end fixing plate frame 24 is installed at both ends of the inside of the air guide housing 16, and the air duct 25 is installed inside the end fixing plate frame 24.

In this embodiment, an inner spiral cooling tube 26 is disposed inside the air duct 25, two ends of the inner spiral cooling tube 26 penetrate through the air duct 25 and the cooling bin 14, a winding tube 27 is wound on the outer side of the air duct 25, and two ends of the winding tube 27 penetrate through the cooling bin 14

In this embodiment, the wind cooling assembly includes fan 21, end fan storehouse 15 and wind scooper 16, and end fan storehouse 15 is installed to the both ends of cooling storehouse 14, and the inside in end fan storehouse 15 is equipped with fan 21, and the outside in end fan storehouse 15 communicates there is wind scooper 16.

In this embodiment, the air-cooled hot water unit further includes the following usage methods:

step two: when moving, the cross 11, the end hinged sliding block 9, the end fixed plate frame 24 and the wall sliding rail 28 are matched with each other to perform movement buffering;

step three: the double-headed motor 20 is started to adjust the horizontal adjusting screw rod 6 to rotate, and the horizontal adjusting plate 3 is adjusted through the horizontal adjusting screw rod 6 to drive the supporting plate 4 to adjust the distance;

step four: the adjusting seat 22 is adjusted through the starting end fixing plate frame 24 to drive the arc-shaped solar panel 13 to perform azimuth rotation adjustment, so that reflected light of the arc-shaped solar panel 13 irradiates the outer side of the cooling bin 14;

step five: the inner spiral cooling tube 26 is insulated by reflecting light and irradiating on the cooling bin 14 and penetrating through the cooling bin 14 and irradiating on the air duct 25 in winter;

step six: in summer, cold water is led into the winding pipe 27, and the winding pipe 27 is wound on the outer side of the air duct 25 to cool and heat exchange the hot water of the inner spiral cooling pipe 26 in the air duct 25;

step seven: in rainy days, rainwater is guided into the liquid guide inner frame 17 through the arc-shaped liquid guide seat 5 and the arc-shaped solar panel 13, so that the rainwater collides with the outer side edge of the power generation roller 18 to drive the power generation roller 18 to rotate so as to regulate the power generator 7 to generate power;

step eight: the blower 21 is started to lead the wind into the blower 21 through the wind scooper 16 and enters the wind guide barrel 25 through the blower 21 to penetrate through the wind guide barrel 25 to cool the inner spiral cooling pipe 26.

The above is merely a further embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art will be able to apply equivalents and modifications according to the technical solution and the concept of the present invention within the scope of the present invention disclosed in the present invention.

Claims

1. The utility model provides a heat recovery formula and can low temperature operation's hot and cold water unit of heat recovery type module wind which characterized in that: the cooling device comprises a base (1), wherein side sliding rails (2) are arranged on two sides of the top of the base (1), a horizontal adjusting plate (3) capable of sliding on the side sliding rails (2) is sleeved at two ends of the outer side of the side sliding rails (2), a buffer frame component is arranged at the top of the horizontal adjusting plate (3), a supporting plate (4) is arranged at the top of the buffer frame component, an arc-shaped liquid guide seat (5) is arranged at the top of the supporting plate (4), an angle adjusting component is arranged at the top middle part of the arc-shaped liquid guide seat (5), an arc-shaped solar panel (13) is arranged on the angle adjusting component, a horizontal adjusting component capable of driving the horizontal adjusting plate (3) is arranged at the top middle part of the base (1), a U-shaped frame (8) is arranged at two sides of the top of the base (1), a hydraulic power generating component is arranged at the inner middle part of the U-shaped frame (8), the hydraulic power generating component is matched with the arc-shaped liquid guide seat (5) and the arc-shaped solar panel (13), a cooling component is arranged at the top part of the U-shaped frame (8), a liquid guide plate (12) is arranged at the top part of the top of the U-shaped frame (8), and cooling components are arranged at two ends of the cooling bin (14), and cooling components are communicated with each other;

the buffer frame assembly comprises wall slide rails (28), end hinged sliding blocks (9), buffer cross frames (11) and end fixing plate frames (24), wherein the wall slide rails (28) are arranged at the top of the horizontal adjusting plate (3) and at the bottom of the supporting plate (4), the outer sides of the wall slide rails (28) are sleeved with the end hinged sliding blocks (9), the buffer cross frames (11) are hinged between the end hinged sliding blocks (9), and the end fixing plate frames (24) are hinged between the buffer cross frames (11);

the angle adjusting assembly comprises a side hinging seat (19), an adjusting seat (22) and an adjusting motor (23), wherein the side hinging seat (19) is arranged at the side middle part of the arc-shaped liquid guide seat (5), the adjusting motor (23) is arranged at the top part of one side of the side hinging seat (19), the output end of the adjusting motor (23) penetrates through the side hinging seat (19) to be provided with the adjusting seat (22), and the arc-shaped solar panel (13) is arranged at the outer end part of the adjusting seat (22);

the horizontal adjusting assembly comprises a double-headed motor (20) and a horizontal adjusting screw rod (6), the double-headed motor (20) is arranged at the top middle part of the base (1), the horizontal adjusting screw rod (6) is arranged at two output ends of the double-headed motor (20), and the horizontal adjusting screw rod (6) penetrates through the horizontal adjusting plate (3) and is meshed with the horizontal adjusting plate (3);

the hydroelectric power generation assembly comprises a generator (7), a liquid guide inner frame (17), a connecting rotating rod and a power generation roller (18), wherein the liquid guide inner frame (17) is arranged at the middle part of the inner side of the U-shaped frame (8), the generator (7) is arranged at two ends of one side of the liquid guide inner frame (17), the output end of the generator (7) penetrates through the liquid guide inner frame (17) to be provided with the connecting rotating rod, and the power generation roller (18) is sleeved on the outer side of the connecting rotating rod;

the wind cooling assembly comprises a fan (21), an end fan bin (15) and a wind scooper (16), wherein the end fan bin (15) is arranged at two ends of the cooling bin (14), the fan (21) is arranged in the end fan bin (15), and the wind scooper (16) is communicated with the outer side of the end fan bin (15).

2. The heat-accumulating and low-temperature-operation heat-recovery type modularized air-cooled hot water unit according to claim 1, wherein: the water cooling assembly comprises an end fixing plate frame (24), an air duct (25), an inner spiral cooling pipe (26) and a winding pipe (27), wherein the end fixing plate frame (24) is installed at two ends of the inside of the air guide cover (16), and the air duct (25) is installed in the end fixing plate frame (24).

3. The heat-accumulating and low-temperature-operation heat-recovery type modularized air-cooled hot water unit according to claim 2, wherein: the inside of air duct (25) is equipped with interior spiral cooling tube (26), air duct (25) and cooling storehouse (14) are run through at the both ends of interior spiral cooling tube (26), the outside winding of air duct (25) has winding pipe (27), cooling storehouse (14) are run through at the both ends of winding pipe (27).

4. A regenerative and low temperature operable modular air-cooled hot water unit according to claim 3, wherein: the air-cooled hot water unit also comprises the following using method:

step two: when moving, the cross frame (11), the end hinged sliding block (9), the end fixed plate frame (24) and the wall sliding rail (28) are matched with each other to perform moving buffering;

step three: starting a double-headed motor (20) to adjust the rotation of a horizontal adjusting screw (6), and adjusting a horizontal adjusting plate (3) through the horizontal adjusting screw (6) to drive a supporting plate (4) to adjust the distance;

step four: the adjusting seat (22) is adjusted through the starting end fixing plate frame (24) to drive the arc-shaped solar panel (13) to perform azimuth rotation adjustment, so that reflected light of the arc-shaped solar panel (13) irradiates the outer side of the cooling bin (14);

step five: the inner spiral cooling tube (26) is insulated by reflecting light and irradiating on the cooling bin (14) and penetrating through the cooling bin (14) and irradiating on the air duct (25) in winter;

step six: in summer, cold water is led into the winding pipe (27), and the winding pipe (27) is wound on the outer side of the air duct (25) to cool and heat exchange hot water of the inner spiral cooling pipe (26) in the air duct (25);

step seven: in rainy days, rainwater is guided into the liquid guide inner frame (17) through the arc-shaped liquid guide seat (5) and the arc-shaped solar panel (13), so that the rainwater collides with the outer side edge of the power generation roller (18) to drive the power generation roller (18) to rotate so as to regulate the power generator (7) to generate power;

step eight: the fan (21) is started to lead the wind into the fan (21) through the wind scooper (16) and enter the air duct (25) through the fan (21) to penetrate through the air duct (25) to cool the inner spiral cooling pipe (26).