CN116624995A - Renewable energy source and building integrated comprehensive utilization system - Google Patents

Abstract

The invention relates to a renewable energy source and building integrated comprehensive utilization system which comprises a pipeline opening and closing unit and a heat exchange and flow-around unit, wherein the pipeline opening and closing unit comprises a heat exchange box, an air inlet pipe is fixedly arranged on the side wall of the heat exchange box, a power box is fixedly arranged in the center of the air inlet pipe, the heat exchange and flow-around unit comprises a storage barrel, a heat exchange pipe is fixedly arranged at the bottom of the storage barrel, the heat exchange pipe is inserted and arranged in the heat exchange box, a second sealing plug is inserted and arranged in the heat exchange pipe, and a disturbance component is fixedly arranged in the second sealing plug. According to the invention, the pipeline opening and closing unit and the heat exchange bypass unit are arranged, so that when the hot air of the device is in the same state, the internal pipeline opening and closing unit enables the connecting pipeline to be opened, the internal gas can be conveniently moved, and under the condition that the pipeline is opened, the internal heat exchange bypass unit moves under the driving of the pipeline opening and closing unit, so that the moisture in the heat exchange pipe is rotated, the heat transfer efficiency is improved, and the device is suitable for wide popularization.

Description

Renewable energy source and building integrated comprehensive utilization system

Technical Field

The invention relates to the technical field of green buildings, in particular to a renewable energy source and building integrated comprehensive utilization system.

Background

Via search disclosure (bulletin) number: a renewable energy green building integrated system of CN114353301a comprising: the heat exchange recovery box, the heat exchange energy-absorbing assembly, the actuating lever and the circulating liquid box, the both sides of heat exchange recovery box are equipped with respectively and advance air guide mouth and discharge the guide mouth, and the inside movable mounting of heat exchange recovery box has the motion push pedal, and the quantity of heat exchange energy-absorbing assembly is a plurality of and evenly is fixed in the inboard of heat exchange recovery box and the bottom and the top surface fixed connection of motion push pedal of heat exchange energy-absorbing assembly. According to the invention, the heat pipe heat exchange structure is arranged, the heat exchange recovery box is utilized to carry out external discharge of heat energy of an air conditioner external unit, and heat energy is exchanged with the surface heat energy of the heat exchange energy absorption assembly through hot flow gas, so that liquid such as water liquid is heated, the heat energy is recovered and reused for people in a building, and the problem of waste of directly discharging the heat energy to outdoor heat energy is avoided, and energy regeneration is carried out.

But the present inventors have found that this technical solution still has at least the following drawbacks:

in the actual use process, the air conditioner external unit is not always in a working state, when the temperature reaches the timing temperature, the air conditioner external unit stops working at the moment, the device cannot perform heat exchange and energy absorption operation, and because the whole heat exchange and recovery box is in an open state at the moment, external air can enter the heat exchange and recovery box through the outlet, thereby finishing the heat exchange and energy absorption operation inside, and the external air is generally lower than the temperature of the air outlet, thereby enabling the energy exchange operation, enabling the medium heated to be cooled again, finally enabling heat energy to be unnecessarily lost, and affecting the recycling rate.

Disclosure of Invention

The invention aims to provide a renewable energy source and building integrated comprehensive utilization system, which solves the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: a renewable energy source and building integrated comprehensive utilization system comprises,

the pipeline opening and closing unit comprises a heat exchange box, an air inlet pipe is fixedly arranged on the side wall of the heat exchange box, a power box is fixedly arranged at the central position of the air inlet pipe, a rotating shaft is movably arranged in the power box in a penetrating mode, a rolling plate is fixedly arranged on the surface of the rotating shaft, a rotary table is fixedly arranged at the tail end of the rotating shaft, and a valve opening driving assembly used for driving the air inlet pipe is arranged on the side wall of the rotary table in a lap joint mode;

the heat exchange bypass unit comprises a storage barrel, a heat exchange pipe is fixedly arranged at the bottom of the storage barrel, the heat exchange pipe is inserted and arranged in the heat exchange box, a second sealing plug is inserted and arranged in the heat exchange pipe, and a disturbance component is fixedly arranged in the second sealing plug;

and the pipeline opening and closing unit drives the disturbance assembly to complete the up-and-down movement of the second sealing plug through the turntable in the process of opening the internal valve.

As a preferred implementation mode of the invention, the side wall of the heat exchange box is fixedly provided with an air outlet pipe, the tail ends of the air outlet pipe and the air inlet pipe are fixedly provided with connecting flanges, the surfaces of the connecting flanges are provided with a plurality of mounting holes, the inside of the air inlet pipe is fixedly provided with a guide plate, and the outlet position of the guide plate is positioned below the air inlet pipe.

As a preferred implementation mode of the invention, the driving assembly comprises a positioning sleeve, the positioning sleeve is fixedly arranged on the side wall of the air inlet pipe, a cavity is formed in the positioning sleeve, a limit guide rail is fixedly arranged in the cavity, a limit slide block is slidably arranged on the surface of the limit guide rail, a first baffle is fixedly arranged at the center of the limit slide block, a plug rod is fixedly arranged at the bottom of the first baffle, the plug rod penetrates through the side wall of the positioning sleeve, and a supporting plate is fixedly arranged at the tail end of the plug rod.

As a preferred implementation mode of the invention, the side wall of the supporting plate is provided with a pressing plate in a lap joint mode, the pressing plate is fixedly arranged on the side wall of the turntable, the other side wall of the supporting plate is fixedly provided with a first connecting rod, the side wall of the first connecting rod is provided with a limiting seat in a sliding mode, and the limiting seat is fixedly arranged on the side wall of the air inlet pipe.

As a preferred implementation mode of the invention, the upper surface of the first baffle is fixedly provided with the ejector rod, the ejector rod movably penetrates through the whole positioning sleeve, the side wall of the ejector rod positioned in the positioning sleeve is sleeved with the first spring, two ends of the first spring are respectively fixedly arranged on the side wall of the positioning sleeve and the upper surface of the first baffle, the first spring is in a compressed state, the tail end of the ejector rod is fixedly provided with the transverse plate, the bottom of the center of the transverse plate is fixedly provided with the positioning bulge, and the tail end of the positioning bulge vertically corresponds to the cylindrical through hole formed in the surface of the air inlet pipe.

As a preferred implementation mode of the invention, the sealing doors are movably arranged on one sides of the air outlet pipe and the air inlet pipe, which are mutually abutted, the sealing doors are matched with the air outlet pipe and the air inlet pipe in size, a movable sliding groove is formed in the air inlet pipe, a movable sliding block is slidably arranged on the surface of the movable sliding groove, a clamping block is fixedly arranged at one end of the movable sliding block, the surface of the clamping block is subjected to chamfering treatment, the chamfering position of the clamping block is correspondingly arranged below the cylindrical through hole, a push rod is fixedly arranged on the other side wall of the movable sliding block, and the tail end of the push rod is mutually attached to the sealing door at the tail end of the air inlet pipe.

As a preferred implementation mode of the invention, the surface of the sealing door is obliquely arranged, the inclined surface of the sealing door is fixedly provided with a positioning sliding rail, the surface of the positioning sliding rail is slidably provided with a positioning sliding block, the surface of the positioning sliding block is fixedly provided with a cross rod, the center position of the cross rod is fixedly provided with a second connecting rod, the tail end of the second connecting rod is fixedly provided with a second baffle, the second baffle is movably arranged in a sleeve fixedly arranged at the top of the heat exchange box, and the second baffle and the side wall of the sleeve are fixedly provided with a second spring.

As a preferred implementation mode of the invention, the bottom of the storage barrel is fixedly provided with a plurality of support columns, the support columns are fixedly arranged at the top of the heat exchange box, the bottom of the storage barrel is provided with a heat exchange cavity, the heat exchange cavity is identical to the cavity inside the heat exchange tube, the side wall of the heat exchange cavity is fixedly provided with an L-shaped cavity, the inside of the L-shaped cavity is slidably provided with a first sealing plug, the top of the first sealing plug is fixedly provided with a third connecting rod, the tail end of the third connecting rod is fixedly provided with a third baffle, the tail end of the third baffle is movably arranged inside the limiting sleeve, the limiting sleeve is fixedly arranged inside the storage barrel, and a third spring is fixedly arranged between the third baffle and the inside of the limiting sleeve.

As a preferred embodiment of the invention, the disturbance component comprises a first bracket, the top of the first bracket is fixedly provided with a mounting plate, the top of the mounting plate is fixedly provided with a vertical rod, the vertical rod movably penetrates through the storage barrel, the bottom of the first bracket is fixedly provided with a second sealing plug, a mounting groove is formed in the second sealing plug, the mounting groove is a through hole, the side wall of the mounting groove is movably provided with a pair of partition plates, the bottom of the second sealing plug is fixedly provided with a fixing block, and the upper surface of the fixing block is mutually attached to the partition plates.

As a preferred implementation mode of the invention, the side wall of the vertical rod is fixedly provided with a second push plate, the second push plate and the first push plate fixed on the side wall of the third connecting rod correspond to each other, the first push plate is higher than the second push plate in height, the tail end of the vertical rod is fixedly provided with a second bracket, the side wall of the second bracket is slidably provided with a positioning seat, the positioning seat is fixedly arranged at the top of the power box, the tail end of the second bracket is fixedly provided with a strip-shaped connecting ring, the inner part of the strip-shaped connecting ring is movably sleeved with a guide protrusion, and the guide protrusion is fixedly arranged on the surface of the turntable.

Compared with the prior art, the invention has the following beneficial effects:

according to the integrated comprehensive utilization system for renewable energy and a building, the pipeline opening and closing unit and the heat exchange bypass unit are arranged, when hot air of the integrated comprehensive utilization system is in the same state, the connecting pipeline is opened through the pipeline opening and closing unit, so that the internal gas can conveniently move, and under the condition that the pipeline is opened, the internal heat exchange bypass unit moves under the driving of the pipeline opening and closing unit, so that the moisture in the heat exchange pipe is rotated, and the heat transfer efficiency is improved.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of the overall structure of a renewable energy and building integrated comprehensive utilization system of the present invention;

FIG. 2 is an enlarged view of position A of the integrated comprehensive utilization system of renewable energy and construction of the invention;

FIG. 3 is a partial cross-sectional view of the A-site of the renewable energy and building integrated comprehensive utilization system of the present invention;

FIG. 4 is a schematic diagram of the internal structure of a renewable energy and building integrated comprehensive utilization system according to the present invention;

FIG. 5 is an enlarged view of the B site of the integrated comprehensive utilization system of renewable energy and construction according to the present invention;

FIG. 6 is a cross-sectional view of a renewable energy and building integrated comprehensive utilization system of the present invention at C;

FIG. 7 is a sectional view of a storage tank of the renewable energy and construction integrated comprehensive utilization system of the present invention;

FIG. 8 is an enlarged view of the position D of the integrated comprehensive utilization system of renewable energy and construction.

In the figure:

100. a pipe opening and closing unit; 101. a heat exchange box; 1011. an air outlet pipe; 1012. an air inlet pipe; 1013. a power box; 1014. a connecting flange; 1015. a mounting hole; 102. a rotation shaft; 1021. a rolling plate; 1022. a deflector; 103. a turntable; 1031. a pressing plate; 104. a positioning sleeve; 1041. a spacing guide rail; 1042. a limit sliding block; 105. a rod; 1051. a first baffle; 1052. a first spring; 106. a support plate; 1061. a first connecting rod; 1062. a limit seat; 107. a push rod; 1071. a cross plate; 1072. positioning the bulge; 1073. a cylindrical through hole; 108. moving the slide block; 1081. moving the chute; 1082. a clamping block; 1083. a push rod; 109. sealing the door; 1091. positioning a sliding rail; 1092. positioning a sliding block; 1093. a cross bar; 110. a second connecting rod; 1101. a sleeve; 1102. a second spring; 1103. a second baffle;

200. a heat exchange bypass unit; 201. a storage tub; 2011. a support column; 2012. a heat exchange tube; 2013. a heat exchange cavity; 2014. an L-shaped cavity; 202. a first sealing plug; 2021. a third connecting rod; 2022. a limit sleeve; 2023. a third spring; 2024. a third baffle; 2025. a first push plate; 203. a second sealing plug; 2031. a mounting groove; 2032. a fixed block; 2033. a partition plate; 204. a first bracket; 2041. a mounting plate; 2042. a vertical rod; 2043. a second push plate; 205. a second bracket; 2051. a positioning seat; 2052. a bar-shaped connecting ring; 2053. and a guide protrusion.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Examples

Referring to fig. 1-8, the present invention provides a technical solution: a renewable energy source and building integrated comprehensive utilization system comprises,

the pipeline opening and closing unit 100 comprises a heat exchange box 101, an air inlet pipe 1012 is fixedly arranged on the side wall of the heat exchange box 101, a power box 1013 is fixedly arranged in the center of the air inlet pipe 1012, a rotating shaft 102 is movably arranged in the power box 1013 in a penetrating mode, a rolling plate 1021 is fixedly arranged on the surface of the rotating shaft 102, a rotary disc 103 is fixedly arranged at the tail end of the rotating shaft 102, and a valve opening driving assembly used for driving the air inlet pipe 1012 is arranged on the side wall of the rotary disc 103 in a lap joint mode;

the heat exchange and flow-around unit 200, the heat exchange and flow-around unit 200 comprises a storage barrel 201, a heat exchange tube 2012 is fixedly arranged at the bottom of the storage barrel 201, the heat exchange tube 2012 is inserted and arranged inside the heat exchange box 101, a second sealing plug 203 is inserted and arranged inside the heat exchange tube 2012, and a disturbance component is fixedly arranged inside the second sealing plug 203;

through being provided with pipeline switching unit and heat transfer detouring unit, thereby the hot-blast in the device is in under the same state, thereby makes connecting tube open through inside pipeline switching unit, and the gas of convenient inside removes to under the circumstances that the pipeline was opened, the inside heat transfer detouring unit removes under the drive of pipeline switching unit this moment, thereby rotates the inside moisture of heat transfer pipe, thereby improves the efficiency of heat transfer.

Referring to fig. 1-8, in a specific embodiment, an air outlet pipe 1011 is fixedly disposed on a side wall of the heat exchange box 101, a connection flange 1014 is fixedly disposed at ends of the air outlet pipe 1011 and the air inlet pipe 1012, a plurality of mounting holes 1015 are formed on a surface of the connection flange 1014, a deflector 1022 is fixedly disposed inside the air inlet pipe 1012, and an outlet of the deflector 1022 is located below the air inlet pipe 1012. Through the cooperation of the connecting flange 1014 and the mounting hole 1015, the air inlet pipe 1012 at the moment can be arranged at the air outlet position of the air conditioner external unit, when the air conditioner starts to be started, the external unit synchronously starts to move at the moment, and hot air of the external unit enters the device through the air inlet pipe 1012.

Referring to fig. 1-8, the driving assembly includes a positioning sleeve 104, the positioning sleeve 104 is fixedly disposed on a sidewall of the air inlet pipe 1012, a cavity is formed in the positioning sleeve 104, a limit guide rail 1041 is fixedly disposed in the cavity, a limit slider 1042 is slidably disposed on a surface of the limit guide rail 1041, a first baffle 1051 is fixedly disposed at a central position of the limit slider 1042, an inserting rod 105 is fixedly disposed at a bottom of the first baffle 1051, the inserting rod 105 movably penetrates through the sidewall of the positioning sleeve 104, and a supporting plate 106 is fixedly disposed at an end of the inserting rod 105. The turntable 103 starts to rotate, the pressing plate 1031 on the surface is driven to rotate, the pressing plate 1031 drives the supporting plate 106 to move downwards along with the movement of the pressing plate 1031, and the inserting rod 105 on the surface starts to move downwards in the process of moving the supporting plate 106 downwards.

Referring to fig. 1-8, a pressing plate 1031 is disposed on a side wall of the supporting plate 106 in a lap joint manner, the pressing plate 1031 is fixedly disposed on a side wall of the turntable 103, a first connecting rod 1061 is fixedly disposed on another side wall of the supporting plate 106, a limiting seat 1062 is slidably disposed on a side wall of the first connecting rod 1061, and the limiting seat 1062 is fixedly disposed on a side wall of the air inlet pipe 1012. During the downward movement of the support plate 106, the first connecting rod 1061 moves along the limiting seat 1062, and the limiting purpose is achieved through the limiting seat 1062.

Referring to fig. 1-8, an ejector rod 107 is fixedly arranged on the upper surface of the first baffle 1051, the ejector rod 107 movably penetrates through the whole positioning sleeve 104, a first spring 1052 is sleeved on the side wall of the ejector rod 107 inside the positioning sleeve 104, two ends of the first spring 1052 are respectively and fixedly arranged on the side wall of the positioning sleeve 104 and the upper surface of the first baffle 1051, the first spring 1052 is in a compressed state, a transverse plate 1071 is fixedly arranged at the tail end of the ejector rod 107, a positioning protrusion 1072 is fixedly arranged at the bottom of the center of the transverse plate 1071, and the tail end of the positioning protrusion 1072 vertically corresponds to a cylindrical through hole 1073 formed in the surface of the air inlet pipe 1012. The outlet duct 1011 and intake pipe 1012 all move and are provided with sealing door 109 in mutual lean on one side, and sealing door 109 and outlet duct 1011 and intake pipe 1012 size adaptation, and the inside removal spout 1081 that has seted up of intake pipe 1012, removal spout 1081 surface slip is provided with removes slider 108, and remove slider 108 one of them end fixedly is provided with fixture block 1082, and the fixture block 1082 surface carries out the chamfer and handles, and fixture block 1082 chamfer department corresponds the setting in cylinder through-hole 1073 below, remove slider 108 another lateral wall fixedly is provided with push rod 1083, and the terminal sealing door 109 of push rod 1083 and intake pipe 1012 are laminated each other. In the downward movement of the support plate 106, the ejector rod 107 and the cross plate 1071 on the surface start to move downward, so that the positioning protrusion 1072 at the bottom of the cross plate 1071 starts to move inward of the cylindrical through hole 1073, and along with the movement of the positioning protrusion 1072, the bottom of the positioning protrusion 1072 starts to contact with the fixture block 1082 subjected to chamfering at this time, and the fixture block 1082 starts to move leftward due to chamfering treatment of the surface of the fixture block 1082, so that the moving slide block 108 at this time moves along the moving slide groove 1081, and further the push rod 1083 on the surface lifts the sealing door 109, so that the sealing door 109 rotates around the rotation center, and the sealing door 109 is opened.

Referring to fig. 1-8, the surface of the sealing door 109 is obliquely arranged, the inclined surface of the sealing door 109 is fixedly provided with a positioning sliding rail 1091, the surface of the positioning sliding rail 1091 is slidably provided with a positioning sliding block 1092, the surface of the positioning sliding block 1092 is fixedly provided with a cross rod 1093, a second connecting rod 110 is fixedly arranged in the center of the cross rod 1093, the tail end of the second connecting rod 110 is fixedly provided with a second baffle 1103, the second baffle 1103 is movably arranged inside a sleeve 1101 fixedly arranged at the top of the heat exchange box 101, and the second baffle 1103 and the side wall of the sleeve 1101 are fixedly provided with a second spring 1102. After the sealing doors 109 on the right side are opened, the positioning sliding blocks 1092 on the surface start to move upwards along the positioning sliding rail 1091, so that the cross bars 1093 are driven to start to move upwards, the leftmost sealing door 109 is driven to start to rotate, the two sealing doors 109 are opened, and in the upward movement of the cross bars 1093, the second connecting rod 110 and the second baffle 1103 move upwards, the purpose of compressing the second spring 1102 is achieved, and the two sealing doors 109 at the later stage are convenient to reset.

Examples

The difference from this embodiment based on the above embodiment is that:

referring to fig. 1-8, in the present embodiment, a plurality of support columns 2011 are fixedly disposed at the bottom of the storage barrel 201, the support columns 2011 are fixedly disposed at the top of the heat exchange box 101, a heat exchange cavity 2013 is disposed at the bottom of the storage barrel 201, the heat exchange cavity 2013 is the same as an inner cavity of the heat exchange tube 2012, an L-shaped cavity 2014 is fixedly disposed on a side wall of the heat exchange cavity 2013, a first sealing plug 202 is slidably disposed inside the L-shaped cavity 2014, a third connecting rod 2021 is fixedly disposed at the top of the first sealing plug 202, a third baffle 2024 is fixedly disposed at an end of the third connecting rod 2021, a third baffle 2024 is movably disposed inside the limiting sleeve 2022, the limiting sleeve 2022 is fixedly disposed inside the storage barrel 201, and a third spring 2023 is fixedly disposed between the third baffle 2024 and the inside the limiting sleeve 2022. After the second support 205 starts to move upwards, the second sealing plug 203 is driven by the vertical rod 2042, the mounting plate 2041 and the first support 204 to start to move upwards, during the upward movement of the second sealing plug 203, the moisture in the heat exchange tube 2012 starts to move upwards, the L-shaped cavity 2014 is sealed by the first sealing plug 202, so that the moisture can only move upwards, when the second sealing plug 203 starts to exceed the L-shaped cavity 2014, the second push plate 2043 is contacted with the first push plate 2025, so that the third connecting rod 2021 on the jacking surface starts to move upwards, the third spring 2023 in the storage barrel 201 starts to compress, the third spring 2023 is convenient for later resetting, and the first sealing plug 202 is separated from the L-shaped cavity 2014, so that cold water in the storage barrel 201 enters the heat exchange tube 2012 through the L-shaped cavity 2014.

Referring to fig. 1-8, the disturbance component includes a first support 204, a mounting plate 2041 is fixedly disposed at the top of the first support 204, a vertical rod 2042 is fixedly disposed at the top of the mounting plate 2041, the vertical rod 2042 movably penetrates through the storage barrel 201, a second sealing plug 203 is fixedly disposed at the bottom of the first support 204, a mounting groove 2031 is formed in the second sealing plug 203, the mounting groove 2031 is a through hole, a pair of partition plates 2033 are movably disposed on the side walls of the mounting groove 2031, fixing blocks 2032 are fixedly disposed at the bottom of the second sealing plug 203, and the upper surfaces of the fixing blocks 2032 are mutually attached to the partition plates 2033. After the second support 205 starts to move downwards, the second sealing plug 203 on the surface moves downwards at this time, when the second sealing plug 203 moves to the inside of the heat exchange cavity 2013, the internal water jacking partition 2033 rotates, so that the water flow can be ensured to flow finally, but the rotation path of the partition 2033 is locked by the fixing block 2032 when the second sealing plug 203 moves upwards, so that the jacked water flow is ensured not to leak.

Referring to fig. 1-8, a second push plate 2043 is fixedly disposed on a side wall of the vertical rod 2042, the second push plate 2043 and a first push plate 2025 fixed on a side wall of the third connecting rod 2021 correspond to each other, the first push plate 2025 is higher than the second push plate 2043, a second bracket 205 is fixedly disposed at an end of the vertical rod 2042, a positioning seat 2051 is slidably disposed on a side wall of the second bracket 205, the positioning seat 2051 is fixedly disposed at a top of the power box 1013, a bar-shaped connecting ring 2052 is fixedly disposed at an end of the second bracket 205, guide protrusions 2053 are movably sleeved in the bar-shaped connecting ring 2052, and the guide protrusions 2053 are fixedly disposed on a surface of the turntable 103. In the process of starting rotating the turntable 103, the surface of the turntable 103 is provided with a guide protrusion 2053, the surface of the guide protrusion 2053 is sleeved with a strip-shaped connecting ring 2052, the second support 205 connected with the strip-shaped connecting ring 2052 is limited by the positioning seat 2051, and finally the second support 205 can be driven to reciprocate up and down through the turntable 103.

It should be noted that the invention is a renewable energy source and building integrated comprehensive utilization system, each part is a general standard part or a part known to a person skilled in the art, and the structure and principle of the system are known by the person skilled in the art through technical manuals or through routine experimental methods.

Working principle:

both seal doors 109 are in a closed state before the device is used;

through the cooperation of the connecting flange 1014 and the mounting hole 1015, the air inlet pipe 1012 at the moment can be arranged at the air outlet position of the air conditioner external unit, when the air conditioner starts to be started, the external unit synchronously starts to move at the moment, and hot air of the external unit enters the device through the air inlet pipe 1012.

Firstly, the hot air is acted by the deflector 1022 at this time, so that the wind at this time has a tendency to blow upwards, when the hot air contacts the rolling plate 1021, the rolling plate 1021 starts to be subjected to the force of the wind at this time, so that the rolling plate 1021 starts to rotate, and the central rotating shaft 102 is driven to rotate, and the rotating shaft 102 rotates to drive the rotating disc 103 with the fixed end to start rotating, and the rotating disc 103 starts to rotate, and the pressing plate 1031 with the surface starts to rotate, and as the pressing plate 1031 moves, the supporting plate 106 at this time is driven to move downwards by the pressing plate 1031, during the downward movement of the supporting plate 106, the inserting rod 105 with the surface starts to move downwards, so as to drive the first baffle 1051 with the surface to move downwards, and elongate the first spring 1052 at this time, and as the supporting plate 106 moves downwards, the pressing plate 1031 rotates, finally the pressing plate 1031 will be separated from the supporting plate 106, and the first spring 1052 in this time moves the supporting plate 106 upwards, but does not move upwards, and the next pressing plate 1031 holds the supporting plate 106 against the existing state periodically.

When the supply of wind is stopped, the first spring 1052 will move the pressing plate 1031 in the opposite direction, thereby achieving a reset effect and ensuring that the sealing door 109 is sealed again at a later stage.

During the downward movement of the support plate 106, the first connecting rod 1061 moves along the limiting seat 1062, and the limiting purpose is achieved through the limiting seat 1062.

In the downward movement of the support plate 106, the ejector rod 107 and the cross plate 1071 on the surface start to move downward, so that the positioning protrusion 1072 at the bottom of the cross plate 1071 starts to move inward of the cylindrical through hole 1073, and along with the movement of the positioning protrusion 1072, the bottom of the positioning protrusion 1072 starts to contact with the fixture block 1082 subjected to chamfering at this time, and the fixture block 1082 starts to move leftward due to chamfering treatment of the surface of the fixture block 1082, so that the moving slide block 108 at this time moves along the moving slide groove 1081, and further the push rod 1083 on the surface lifts the sealing door 109, so that the sealing door 109 rotates around the rotation center, and the sealing door 109 is opened.

When the right sealing door 109 is opened, the positioning slider 1092 on the surface starts to move upwards along the positioning sliding rail 1091, so as to drive the cross rod 1093 to start moving upwards, and further drive the leftmost sealing door 109 to start rotating, so that both sealing doors 109 are opened, and in the upward movement of the cross rod 1093, the second connecting rod 110 and the second baffle 1103 move upwards at this time, so as to achieve the purpose of compressing the second spring 1102, and further facilitate the reset operation of the two sealing doors 109 in the later stage.

In the process of starting to rotate the turntable 103, the surface of the turntable 103 is provided with a guide protrusion 2053, at this time, the surface of the guide protrusion 2053 is sleeved with a strip-shaped connecting ring 2052, and the second support 205 connected with the strip-shaped connecting ring 2052 is limited by the positioning seat 2051, and finally, the second support 205 can be driven to reciprocate up and down through the turntable 103.

After the second support 205 starts to move upwards, the second sealing plug 203 is driven by the vertical rod 2042, the mounting plate 2041 and the first support 204 to start to move upwards, during the process of moving upwards the second sealing plug 203, the water inside the heat exchange tube 2012 starts to move upwards, the L-shaped cavity 2014 is sealed by the first sealing plug 202, so that the water can only move upwards, when the second sealing plug 203 starts to exceed the L-shaped cavity 2014, the second push plate 2043 and the first push plate 2025 contact, so that the third connecting rod 2021 on the jacking surface starts to move upwards, the third spring 2023 inside starts to compress, the third spring 2023 is convenient for later resetting, and the first sealing plug 202 is separated from the L-shaped cavity 2014, so that the cold water inside the storage barrel 201 enters the heat exchange tube 2012 through the L-shaped cavity 2014.

When the second support 205 starts to move downwards, the second sealing plug 203 on the surface moves downwards at this time, and when the second sealing plug 203 moves to the inside of the heat exchange cavity 2013, the internal water jacking partition 2033 rotates, so that the water flow can be ensured to flow, but when the second sealing plug 203 moves upwards, the rotation path of the partition 2033 is locked by the fixing block 2032, so that the jacking water flow is ensured not to leak.

Claims (10)

1. The utility model provides a renewable energy and building integration comprehensive utilization system which characterized in that: comprising the steps of (a) a step of,

the pipeline opening and closing unit (100), the pipeline opening and closing unit (100) comprises a heat exchange box (101), an air inlet pipe (1012) is fixedly arranged on the side wall of the heat exchange box (101), a power box (1013) is fixedly arranged at the central position of the air inlet pipe (1012), a rotating shaft (102) is movably arranged in the power box (1013) in a penetrating mode, a rolling plate (1021) is fixedly arranged on the surface of the rotating shaft (102), a rotary disc (103) is fixedly arranged at the tail end of the rotating shaft (102), and a driving assembly for driving an internal valve of the air inlet pipe (1012) to open is arranged on the side wall of the rotary disc (103) in a lap joint mode;

the heat exchange and flow-around unit (200), the heat exchange and flow-around unit (200) comprises a storage barrel (201), a heat exchange pipe (2012) is fixedly arranged at the bottom of the storage barrel (201), the heat exchange pipe (2012) is inserted and arranged inside the heat exchange box (101), a second sealing plug (203) is inserted and arranged inside the heat exchange pipe (2012), and a disturbance component is fixedly arranged inside the second sealing plug (203);

in the process of opening the internal valve, the pipeline opening and closing unit (100) drives the disturbance assembly to complete the up-and-down movement of the second sealing plug (203) through the turntable (103).

2. The renewable energy and building integrated comprehensive utilization system according to claim 1, wherein: the heat exchange box is characterized in that an air outlet pipe (1011) is fixedly arranged on the side wall of the heat exchange box (101), a connecting flange (1014) is fixedly arranged at the tail end of the air outlet pipe (1011) and the tail end of the air inlet pipe (1012), a plurality of mounting holes (1015) are formed in the surface of the connecting flange (1014), a guide plate (1022) is fixedly arranged in the air inlet pipe (1012), and the outlet position of the guide plate (1022) is located below the air inlet pipe (1012).

3. The renewable energy and building integrated comprehensive utilization system according to claim 1, wherein: the driving assembly comprises a locating sleeve (104), the locating sleeve (104) is fixedly arranged on the side wall of the air inlet pipe (1012), a cavity is formed in the locating sleeve (104), a limit guide rail (1041) is fixedly arranged in the cavity, a limit slide block (1042) is arranged on the surface of the limit guide rail (1041) in a sliding mode, a first baffle plate (1051) is fixedly arranged at the central position of the limit slide block (1042), a plug rod (105) is fixedly arranged at the bottom of the first baffle plate (1051), the plug rod (105) movably penetrates through the side wall of the locating sleeve (104), and a supporting plate (106) is fixedly arranged at the tail end of the plug rod (105).

4. A renewable energy and building integrated comprehensive utilization system according to claim 3, wherein: the utility model discloses a gas inlet pipe, including backup pad (106) lateral wall overlap joint is provided with clamp plate (1031), clamp plate (1031) fixed setting is in carousel (103) lateral wall, just backup pad (106) another lateral wall is fixed to be provided with head rod (1061), head rod (1061) lateral wall slides and is provided with spacing seat (1062), just spacing seat (1062) fixed setting is in intake pipe (1012) lateral wall.

5. A renewable energy and building integrated comprehensive utilization system according to claim 3, wherein: the utility model discloses a cylinder through hole (1073) that fixed setting was put in position cover (104) and air intake pipe (1012) surface was seted up, first baffle (1051) upper surface fixed is provided with ejector pin (107), and ejector pin (107) activity run through whole spacer sleeve (104), and the ejector pin (107) lateral wall that is located spacer sleeve (104) inside cup joints and is provided with first spring (1052), first spring (1052) both ends are fixed respectively and are set up at spacer sleeve (104) lateral wall and first baffle (1051) upper surface, first spring (1052) are in compression state, just ejector pin (107) end fixed be provided with diaphragm (1071), diaphragm (1071) center bottom is fixed to be provided with location arch (1072), and the cylinder through hole (1073) that location arch (1072) end and intake pipe (1012) surface were seted up vertically correspond.

6. The renewable energy and building integrated comprehensive utilization system according to claim 1, wherein: the utility model discloses a sealing device for air inlet pipe, including outlet duct (1011) and intake pipe (1012), all move and be provided with sealing door (109) in mutual butt one side, and sealing door (109) and outlet duct (1011) and intake pipe (1012) size adaptation, just inside removal spout (1081) of having seted up of intake pipe (1012), removal spout (1081) surface slip is provided with removal slider (108), and removes slider (108) wherein one end is fixed and be provided with fixture block (1082), and fixture block (1082) surface carries out chamfering, and fixture block (1082) chamfer department corresponds the setting in cylinder through-hole (1073) below, remove slider (108) another lateral wall and fixedly be provided with push rod (1083), and push rod (1083) end and the terminal sealing door (109) of intake pipe (1012) laminating each other.

7. The integrated renewable energy and building comprehensive utilization system according to claim 6, wherein: sealing door (109) surface is slope setting, and sealing door (109) slope surface fixation is provided with location slide rail (1091), location slide rail (1091) surface slip is provided with location slider (1092), and location slider (1092) surface fixation is provided with horizontal pole (1093), and horizontal pole (1093) central point puts fixedly and is provided with second connecting rod (110), and second connecting rod (110) end fixation is provided with second baffle (1103), and second baffle (1103) activity setting is inside sleeve (1101) at the fixed setting in heat exchange box (101) top, just second baffle (1103) and sleeve (1101) lateral wall are fixed and are provided with second spring (1102).

8. The renewable energy and building integrated comprehensive utilization system according to claim 1, wherein: the utility model discloses a heat exchange device, including storage barrel (201), heat exchange box (101) and spacer sleeve (2022), storage barrel (201) bottom is fixed to be provided with a plurality of support columns (2011), and support column (2011) fixed setting is at heat exchange box (101) top, just heat exchange cavity (2013) have been seted up to storage barrel (201) bottom, heat exchange cavity (2013) is the same with heat exchange tube (2012) inside cavity, just heat exchange cavity (2013) lateral wall is fixed to be provided with L shape cavity (2014), the inside slip of L shape cavity (2014) is provided with first sealing plug (202), first sealing plug (202) top is fixed to be provided with third connecting rod (2021), and third connecting rod (2021) end is fixed to be provided with third baffle (2024), third baffle (2024) end activity sets up inside spacer sleeve (2022), and spacer sleeve (2022) are fixed to be provided with third spring (2023) inside storage barrel (201), just between third baffle (2024) and spacer sleeve (2022) inside.

9. The renewable energy and building integrated comprehensive utilization system according to claim 1, wherein: the disturbance subassembly includes first support (204), fixed mounting panel (2041) that is provided with in first support (204) top, and the fixed montant (2042) that is provided with in mounting panel (2041) top, montant (2042) activity runs through storage barrel (201), fixed second sealing plug (203) that is provided with in first support (204) bottom, mounting groove (2031) have been seted up to second sealing plug (203) inside, and mounting groove (2031) are the through-hole, mounting groove (2031) lateral wall activity is provided with a pair of baffle (2033), and fixed block (2032) are provided with in second sealing plug (203) bottom, and fixed block (2032) upper surface and baffle (2033) laminating each other.

10. The integrated renewable energy and building comprehensive utilization system according to claim 9, wherein: the utility model discloses a power box, including power box (1013), including montant (2042), connecting rod (205), connecting rod (2052), first push pedal (2025) that montant (2042) lateral wall is fixed is provided with second push pedal (2043), and first push pedal (2025) that second push pedal (2043) and third connecting rod (2021) lateral wall are fixed correspond each other, and first push pedal (2025) is higher than second push pedal (2043) height, just montant (2042) end fixed is provided with second support (205), second support (205) lateral wall slip is provided with positioning seat (2051), and positioning seat (2051) fixed the setting is at headstock (1013) top, just second support (205) end fixed is provided with bar connecting ring (2052), and bar connecting ring (2052) inside activity cup joints and is provided with direction arch (2053), and direction arch (2053) fixed the setting is on carousel (103) surface.