CN113028622B - Separated heat pipe intelligent energy-saving ventilation and cooling system - Google Patents

Abstract

The invention relates to a cooling system, in particular to a separated heat pipe intelligent energy-saving ventilation cooling system, which comprises an outer cylinder cavity, a cooling pipeline I, a cooling pipeline II, a rotary cavity, an inclined pipeline, a supporting low plate and an intermittent sphere, supply cold pipeline I and supply cold pipeline II and all insert in the urceolus cavity, it is connected with the rotation cavity to rotate on the urceolus cavity, it has the intermittent type spheroid to rotate intermittent type cooperation on the cavity, the intermittent type spheroid is provided with one at least, equal fixedly connected with slope pipeline on every intermittent type spheroid, support low dish fixed connection on supply cold pipeline II, it rotates to connect on rotating the cavity to support the low dish, supply cold pipeline II to pass and support the low dish, supply cold pipeline I produces the cold wind of incline direction through the slope pipeline, supply cold pipeline II to produce the cold wind of vertical direction, the slope wind-force of slope dispersion carries out the forced air cooling to the object that needs the refrigerated all around, supply cold pipeline II vertical wind-force directly to cool off the object on upper portion.

Description

Separated heat pipe intelligent energy-saving ventilation and cooling system

Technical Field

The invention relates to a cooling system, in particular to a separated heat pipe intelligent energy-saving ventilation cooling system.

Background

The direct introduction of fresh air can reduce the indoor temperature, but also inevitably affects the moisture content of the indoor air, especially the low-temperature dry outdoor cold air in winter in northern severe cold or cold regions. In order to meet the indoor humidity requirement, electrode humidification is generally adopted. Since the indoor supply air temperature cannot be lower than the dew point temperature of the indoor air, the outdoor air is first heated. In severe cold or cold regions, outdoor cold air is directly introduced to cool the indoor, the problems of heating and humidifying fresh air must be solved, otherwise, energy cannot be saved, and the energy consumption of the original air conditioning system is increased. If the air is directly sent into a room, the possibility of condensation exists in an air supply pipeline and an air inlet and even on the surface;

for example, publication No. CN207865610U discloses a medium temperature air conditioning system based on a regional cooling system, which includes a water pump, an electric mixed flow three-way valve, a first electric two-way valve, a medium temperature fan coil, and a differential pressure control valve, wherein a control channel of the electric mixed flow three-way valve is connected with a water return pipe of the regional cooling system, a constant flow channel of the electric mixed flow three-way valve is connected with one end of the water pump, and a bypass channel of the electric mixed flow three-way valve is connected with the water return pipe of the medium temperature air conditioning system; a water return pipe of the medium-temperature air conditioning system is connected to a water return pipe of the regional cooling system; two ends of the first electric two-way valve are respectively connected with the other end of the water pump and one end of the medium-temperature fan coil; the other end of the medium temperature fan coil is connected with a water return pipe of the medium temperature air conditioning system; the differential pressure control valve is arranged between a water supply pipe and a water return pipe of the medium-temperature air conditioning system; the utility model has the defect that the uniform cooling can not be dispersed.

Disclosure of Invention

The invention aims to provide an intelligent energy-saving ventilation and cooling system with separated heat pipes, which can uniformly disperse and cool.

The purpose of the invention is realized by the following technical scheme:

energy-conserving ventilation cooling system of disconnect-type heat pipe intelligence, including urceolus cavity, cooling pipeline I, cooling pipeline II, rotation cavity, slope pipeline, support low plate and intermittent type spheroid, cooling pipeline I and cooling pipeline II all insert in the urceolus cavity, rotate on the urceolus cavity and be connected with the rotation cavity, the last intermittent type cooperation of rotation cavity has the intermittent type spheroid, the intermittent type spheroid is provided with one at least, equal fixedly connected with slope pipeline on every intermittent type spheroid, support low plate fixed connection on cooling pipeline II, support the low plate and rotate to connect on rotating the cavity, cooling pipeline II passes the support low plate, cooling pipeline I produces the cold wind of incline direction through the slope pipeline, cooling pipeline II produces the cold wind of vertical direction.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises an installation support, an inner cylinder wall, an arc baffle I and an arc baffle II, wherein an outer cylinder cavity is fixedly connected to the installation support, the inner cylinder wall is fixedly connected to the inner part of the outer cylinder cavity, a sliding cavity is formed between the inner cylinder wall and the outer cylinder cavity, the arc baffle I and the arc baffle II are both slidably connected to the inside of the sliding cavity, and a cooling pipeline I and a cooling pipeline II are respectively and fixedly connected to the arc baffle I and the arc baffle II.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises an air dispersing ring and a mounting support ring, wherein the air dispersing ring is fixedly connected with the cooling pipeline I, the air dispersing ring is in clearance fit with the mounting support ring, and the mounting support ring is fixedly connected to the inner cylinder wall.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a rotating belt wheel and a driving shaft, wherein the rotating belt wheel is fixedly connected to the rotating cavity, the driving shaft is rotatably connected to the mounting bracket, the driving shaft is in transmission connection with the rotating belt wheel, and a driving device for driving the driving shaft to rotate is arranged on the driving shaft.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a telescopic mechanism I, a rotating support ring, a rotating disc and a stirring side lug, wherein the telescopic mechanism I is fixedly connected in the cavity of the outer barrel, the telescopic end of the telescopic mechanism I is fixedly connected with the rotating support ring, the rotating support ring is rotatably connected with the rotating disc, the rotating disc is fixedly connected with the stirring side lug, at least one stirring side lug is arranged, each stirring side lug is provided with a waist hole, and a plurality of inclined pipelines are respectively inserted into the waist holes.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a first height adjusting support, a first telescopic pipeline and a cross air mechanism, wherein the first height adjusting support is fixedly connected to the support low plate, the cross air mechanism is rotatably connected to the first height adjusting support, the cooling pipeline II is connected with the cross air mechanism through the first telescopic pipeline, and the cross air mechanism disperses the wind power in the vertical direction of the cooling pipeline II into transverse wind power; the first height adjusting support comprises an installation cone, a rotary support disc I, a thread cylinder I and a thread rod I, the installation cone is fixedly connected to a support low disc, the installation cone is rotatably connected with two thread rods I, the rotary support disc I is fixedly connected with two thread cylinders I, the two thread rods I are respectively connected to the two thread cylinders I through threads, and a cross wind swivel is rotatably connected to the rotary support disc I; first flexible pipeline includes connecting cylinder I, sliding cylinder I, connecting cylinder I and jet air cavity I, sliding connection has sliding cylinder I between connecting cylinder I and the connecting cylinder I, fixedly connected with jet air cavity I on the connecting cylinder I, I fixed connection of connecting cylinder is on cooling pipeline II, cooling pipeline II and jet air cavity I intercommunication are provided with a plurality of jet air holes on the jet air cavity I, I fixed connection of connecting cylinder is on rotating and propping dish I, jet air cavity I is located horizontal wind runner ring.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises external connecting pipelines, wherein the cooling pipeline I and the cooling pipeline II are both connected with the external connecting pipelines; the external connection pipeline comprises an installation pipeline I, an adjustment pipeline, a connection pipeline, a one-way mechanism and an installation pipeline II, the installation pipeline I and the installation pipeline II are connected in a sliding mode to form the adjustment pipeline, the connection pipeline is fixedly connected to the adjustment pipeline, the one-way mechanism is arranged in the connection pipeline, and the installation pipeline I is fixedly connected to the cooling pipeline I and the cooling pipeline II.

As a further optimization of the technical scheme, the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a second height adjusting bracket, a second telescopic pipeline and a cross wind mechanism, wherein the second telescopic pipeline is detachably and fixedly connected with an external connecting pipeline, the second telescopic pipeline is fixedly connected with a second height adjustment, the second height adjustment is rotatably connected with the cross wind mechanism, and the external connecting pipeline is connected with the cross wind mechanism through the second telescopic pipeline; the second telescopic pipeline comprises a connecting cylinder II, a sliding cylinder II, a connecting cylinder II, an air injection cavity II and pushing columns, the sliding cylinder II is slidably connected between the connecting cylinder II and the connecting cylinder II, the air injection cavity II is fixedly connected to the connecting cylinder II, a plurality of air injection holes are formed in the air injection cavity II, the air injection cavity II is located in the cross air rotating ring, the pushing columns are fixedly connected to the inside of the connecting cylinder II, the connecting cylinder II can be detachably and fixedly connected to the two connecting pipelines, and the two pushing columns are respectively contacted with the two one-way mechanisms; the second height adjustment support is including the installation barrel, rotate and prop dish II, screw thread section of thick bamboo II and threaded rod II, rotates on the installation barrel and is connected with two threaded rod II, all has screw thread section of thick bamboo II through threaded connection on two threaded rod II, and two equal fixed connection of screw thread section of thick bamboo prop the dish II in the rotation, and the cross wind swivel rotates to be connected on rotating and props dish II, and installation barrel fixed connection props II fixed connection on the connecting cylinder, rotates and props II fixed connection on the connecting cylinder II of dish.

As a further optimization of the technical scheme, the split heat pipe intelligent energy-saving ventilation and cooling system comprises a crosswind mechanism, a crosswind swivel, crosswind pipelines and inclined bodies, wherein the crosswind swivel is fixedly connected with the crosswind pipelines, and the inclined bodies are fixedly connected in the crosswind swivel.

As a further optimization of the technical scheme, the split heat pipe intelligent energy-saving ventilation and cooling system comprises a cross wind mechanism, a cross wind pipe and fan blades, wherein the cross wind mechanism comprises a cross wind swivel, the cross wind pipe and the fan blades, the cross wind swivel is fixedly connected with a plurality of cross wind pipes, and the cross wind swivel is internally and fixedly connected with a plurality of fan blades.

The separated heat pipe intelligent energy-saving ventilation and cooling system has the beneficial effects that:

according to the separated heat pipe intelligent energy-saving ventilation and cooling system, cold air can be provided for the outer cylinder cavity through the cooling pipeline I and the cooling pipeline II, the cooling pipeline I is changed into dispersed inclined wind power by the inclined pipeline, the vertical wind power is provided by the cooling pipeline II, the dispersed inclined wind power is used for air-cooling objects needing to be cooled on the periphery, and the vertical wind power of the cooling pipeline II is used for directly cooling the objects on the upper part;

the driving shaft drives the inclined pipelines to rotate, and drives wind in the inclined direction to rotate, so that the wind power is further dispersed; the telescopic end of the telescopic mechanism I moves to adjust the change of the inclination directions of the inclined pipelines;

the first-degree adjusting support, the first telescopic pipeline and the transverse air mechanism are arranged on the cooling pipeline II, vertical wind power of the cooling pipeline II is changed into transversely dispersed wind power, the dispersed wind power cools surrounding objects, and meanwhile, the wind power in the inclined direction generated by the inclined pipeline pushes the transversely dispersed transverse wind power to move upwards, so that the cooling air is ensured not to carry heat to move downwards, and heat accumulation can be prevented;

the length of the external connecting pipeline can be adjusted, so that the device is conveniently installed indoors, and the external connecting pipeline connects the device with the outside;

the second height adjusting bracket, the second telescopic pipeline and the transverse wind mechanism can increase transversely dispersed wind power on the external connecting pipeline, increase the dispersion degree of the wind power and further cool objects; the wind power in the inclined direction generated by matching with the inclined pipeline pushes the transverse wind power generated by transverse dispersion to move upwards, so that the cooling wind is ensured not to carry heat to move downwards, and the heat accumulation can be prevented.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural diagram I of an embodiment of a split heat pipe intelligent energy-saving ventilation and cooling system of the present invention;

FIG. 2 is a schematic structural diagram of a second embodiment of the separated heat pipe intelligent energy-saving ventilation and cooling system of the present invention;

FIG. 3 is a schematic structural diagram of a second embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 4 is a schematic diagram of a third structure of an embodiment of the separated heat pipe intelligent energy-saving ventilation and cooling system of the present invention;

FIG. 5 is a schematic structural diagram of a fourth embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 6 is a schematic structural diagram of a four-sectional view of an embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 7 is a schematic view of a fourth partial structure of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the embodiment of the present invention;

FIG. 8 is a schematic diagram of a fourth partial structure of the intelligent energy-saving ventilation and cooling system with separate heat pipes according to the embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a fifth embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 10 is a schematic structural diagram of a sixth embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 11 is a schematic structural diagram of a five-sectional view of an embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 12 is a schematic diagram of a sixth partial structure of an embodiment of the intelligent energy-saving ventilation and cooling system with separated heat pipes according to the present invention;

FIG. 13 is a schematic diagram of a sixth partial structure of the intelligent energy-saving ventilation and cooling system with separate heat pipes according to the embodiment of the present invention;

FIG. 14 is a schematic diagram of a sixth partial structure of an embodiment of the intelligent energy-saving ventilation and cooling system with separate heat pipes of the present invention;

FIG. 15 is a first structural view of the crosswind mechanism of the present invention;

fig. 16 is a schematic structural view of a crosswind mechanism according to the present invention.

In the figure: a mounting bracket 101; an outer barrel cavity 102; an inner cylindrical wall 103; an arc baffle I104; a cooling pipeline I105; a diffuser ring 106; mounting a support ring 107; a circular arc baffle II 108; a cooling supply pipeline II 109; a rotating chamber 110; the inclined duct 111; a support lower tray 112; a rotating pulley 113; a drive shaft 114; a telescoping mechanism I115; a rotating support ring 116; a rotating disk 117; toggle side tab 118; intermittent spheres 119; a mounting cone 201; rotating the support disc I202; a threaded barrel I203; a threaded rod I204; a connecting cylinder I205; a sliding cylinder I206; a connecting cylinder I207; the air injection cavity I208; a crosswind mechanism 209; cross wind swivel 210; a cross wind duct 211; the tilting body 212; fan blades 213; installing a pipeline I301; adjusting the pipeline 302; a connecting pipe 303; a one-way mechanism 304; installing a pipeline II 305; a connecting cylinder II 401; a sliding cylinder II 403; a connecting cylinder II 404; the air injection cavity II 405; a push post 406; mounting the cylinder 407; rotating the support disc II 408; a threaded cylinder II 409; threaded rod II 410.

Detailed Description

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

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 16, and the separated heat pipe intelligent energy-saving ventilation cooling system includes an outer cylinder cavity 102, a cooling pipeline i 105, a cooling pipeline ii 109, a rotating cavity 110, an inclined pipeline 111, a support low plate 112 and an intermittent sphere 119, the cooling pipeline I105 and the cooling pipeline II 109 are inserted into the outer cylinder cavity 102, the outer cylinder cavity 102 is rotatably connected with a rotating cavity 110, intermittent balls 119 are intermittently matched on the rotating cavity 110, at least one intermittent ball 119 is arranged, each intermittent ball 119 is fixedly connected with an inclined pipeline 111, a support low plate 112 is fixedly connected to the cooling pipeline II 109, the support low plate 112 is rotatably connected to the rotating cavity 110, the cooling pipeline II 109 penetrates through the support low plate 112, the cooling pipeline I105 generates cold air in an inclined direction through the inclined pipeline 111, and the cooling pipeline II 109 generates cold air in a vertical direction; according to the first embodiment illustrated in the attached drawings 1 to 2 of the specification, the device is installed in a room needing air cooling and temperature reduction through an installation bracket 101, a cooling pipeline I105 and a cooling pipeline II 109 are connected to a cold air pipeline, the cold air pipeline can cool the cooling pipeline I105 and the cooling pipeline II 109, the cooling pipeline I105 is connected with a rotary support ring 116, the cold air is introduced into the rotary support ring 116 through the cooling pipeline I105, a plurality of holes are formed in the rotary support ring 116, the cold air in the rotary support ring 116 is dispersed through the rotary support ring 116, a closed space is formed by an outer cylinder cavity 102, a rotary cavity 110 and a support low plate 112, the cold air dispersed through the rotary support ring 116 is discharged through a plurality of inclined pipelines 111 in the closed space, the inclined pipelines 111 are obliquely arranged, the cold air fed into the cooling pipeline I105 is obliquely dispersed and discharged, and the dispersed inclined wind power is used for air cooling objects needing cooling all around, the cooling pipeline II 109 provides wind power in the vertical direction, and the object on the upper part is directly cooled by the vertical wind power of the cooling pipeline II 109.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 16, and the embodiment further describes the first embodiment, the separated heat pipe intelligent energy-saving ventilation and cooling system further includes a mounting bracket 101, an inner cylinder wall 103, an arc baffle i 104, and an arc baffle ii 108, the outer cylinder cavity 102 is fixedly connected to the mounting bracket 101, the inner cylinder wall 103 is fixedly connected to the inside of the outer cylinder cavity 102, a sliding cavity is formed between the inner cylinder wall 103 and the outer cylinder cavity 102, the arc baffle i 104 and the arc baffle ii 108 are both slidably connected in the sliding cavity, and the cooling pipeline i 105 and the cooling pipeline ii 109 are respectively and fixedly connected to the arc baffle i 104 and the arc baffle ii 108; can know in combination with the accompanying drawing, the sliding position of circular arc baffle I104 and circular arc baffle II 108 can be adjusted, and then makes I105 of cooling pipeline and II 109 of cooling pipeline's angle adjust, and then satisfies different installation demands, can fix I105 of cooling pipeline and II 109's of cooling pipeline's position through locking modes such as screws simultaneously.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 16, and the second embodiment is further described in the present embodiment, the separated heat pipe intelligent energy-saving ventilation cooling system further includes an air dispersing ring 106 and a mounting support ring 107, the air dispersing ring 106 is fixedly connected with the cooling pipeline i 105, the air dispersing ring 106 is in clearance fit with the mounting support ring 107, and the mounting support ring 107 is fixedly connected to the inner cylinder wall 103.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 16, and the separated heat pipe intelligent energy-saving ventilation and cooling system further includes a rotating pulley 113 and a driving shaft 114, the rotating pulley 113 is fixedly connected to the rotating cavity 110, the driving shaft 114 is rotatably connected to the mounting bracket 101, the driving shaft 114 is in transmission connection with the rotating pulley 113, and a driving device for driving the driving shaft 114 to rotate is arranged on the driving shaft 114; the driving shaft 114 is provided with a driving device for driving the driving shaft 114 to rotate, the driving shaft 114 drives the rotating belt wheel 113 to rotate, the rotating belt wheel 113 drives the rotating cavity 110 to rotate, and then the inclined pipelines 111 are driven to rotate, so that wind power blown out from the inclined pipelines 111 is further dispersed.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 16, and the separated heat pipe intelligent energy-saving ventilation and cooling system further includes a telescopic mechanism i 115, a rotating support ring 116, a rotating disc 117 and toggle side lugs 118, the telescopic mechanism i 115 is fixedly connected in the outer cylinder cavity 102, the telescopic end of the telescopic mechanism i 115 is fixedly connected with the rotating support ring 116, the rotating support ring 116 is rotatably connected with the rotating disc 117, the toggle side lugs 118 are fixedly connected to the rotating disc 117, at least one toggle side lug 118 is arranged, each toggle side lug 118 is provided with a waist hole, and the plurality of inclined pipelines 111 are respectively inserted into the plurality of waist holes; starting a telescopic mechanism I115, wherein the telescopic mechanism I115 can be a hydraulic cylinder or an electric push rod, the telescopic end of the telescopic mechanism I115 drives a rotary support ring 116 to move, and the rotary support ring 116 drives a rotary disc 117; performing a movement, rotating the disc 117; drive a plurality of side ears 118 of stirring and move, stir side ear 118 and the contact of slope pipeline 111 and promote slope pipeline 111 and move, and then adjust the inclination of slope pipeline 111, preferred telescopic machanism I115 and drive shaft 114 combine to use for slope pipeline 111 can also carry out the adjustment on the angle in the rotatory time, satisfies more user demands.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 16, and the fifth embodiment is further described in the present embodiment, the separated heat pipe intelligent energy-saving ventilation cooling system further includes a first height adjustment bracket, a first telescopic pipeline, and a cross-wind mechanism 209, the first height adjustment bracket is fixedly connected to the support low plate 112, the cross-wind mechanism 209 is rotatably connected to the first height adjustment bracket, the cooling pipeline ii 109 and the cross-wind mechanism 209 are connected by the first telescopic pipeline, and the cross-wind mechanism 209 disperses the wind force in the vertical direction of the cooling pipeline ii 109 into the cross-wind force; the first height adjusting support comprises a mounting cone 201, a rotating support disc I202, threaded cylinders I203 and threaded rods I204, the mounting cone 201 is fixedly connected to the support low disc 112, the mounting cone 201 is rotatably connected with the two threaded rods I204, the rotating support disc I202 is fixedly connected with the two threaded cylinders I203, the two threaded rods I204 are respectively connected to the two threaded cylinders I203 through threads, and a cross wind rotating ring 210 is rotatably connected to the rotating support disc I202; the first telescopic pipeline comprises a connecting cylinder I205, a sliding cylinder I206, a connecting cylinder I207 and an air injection cavity I208, the sliding cylinder I206 is connected between the connecting cylinder I205 and the connecting cylinder I207 in a sliding manner, the air injection cavity I208 is fixedly connected to the connecting cylinder I207, the connecting cylinder I205 is fixedly connected to a cooling pipeline II 109, the cooling pipeline II 109 is communicated with the air injection cavity I208, a plurality of air injection holes are formed in the air injection cavity I208, the connecting cylinder I207 is fixedly connected to a rotary support disc I202, and the air injection cavity I208 is located in a cross air rotary ring 210; the cooling pipeline II 109 is connected to the connecting cylinder I205, wind power of the cooling pipeline II 109 is introduced into the air jetting cavity I208 through the connecting cylinder I205, a plurality of air jetting holes are formed in the air jetting cavity I208, vertical wind power of the cooling pipeline II 109 is changed into transverse wind power through the air jetting cavity I208, cold wind is blown out transversely to cool objects around, meanwhile, the transverse wind mechanism 209 is further installed, the wind power blown out from the air jetting cavity I208 is blown onto the inclined body 212 or the fan blade 213, the inclined body 212 or the fan blade 213 is blown by the wind power to rotate, meanwhile, the transverse wind pipeline 211 is driven to rotate, the wind power blown out transversely originally is enabled to be more dispersed, and the cooling effect is further increased; meanwhile, the wind power in the inclined direction generated by the inclined pipeline 111 pushes the transverse wind power generated by transverse dispersion to move upwards, so that the cooling wind is prevented from carrying heat to move downwards, and the heat accumulation can be prevented; rotate two threaded rods I204, two threaded rods I204 can drive a screw thread section of thick bamboo I203 through the screw thread and move when rotating, and then the height of an adjustment screw thread section of thick bamboo I203, and then the height of adjustment crosswind mechanism 209 satisfies more user demands.

The seventh embodiment:

the sixth embodiment is further described with reference to fig. 1 to 16, and the separated heat pipe intelligent energy-saving ventilation and cooling system further includes an external connection pipeline, where the cooling pipeline i 105 and the cooling pipeline ii 109 are both connected to external connection pipelines; the external connecting pipeline comprises a mounting pipeline I301, an adjusting pipeline 302, a connecting pipeline 303, a one-way mechanism 304 and a mounting pipeline II 305, the adjusting pipeline 302 is connected between the mounting pipeline I301 and the mounting pipeline II 305 in a sliding mode, the connecting pipeline 303 is fixedly connected to the adjusting pipeline 302, the one-way mechanism 304 is arranged in the connecting pipeline 303, and the mounting pipeline I301 is fixedly connected to both the cooling pipeline I105 and the cooling pipeline II 109; through the equal fixed connection of cooling pipeline I105 and cooling pipeline II 109 on installation pipeline I301, length between installation pipeline I301 and the installation pipeline II 305 can be adjusted, the position of adjustment pipeline 302 between installation pipeline I301 and installation pipeline II 305 also can be adjusted simultaneously, and then adjusting device's length, also can connect installation pipeline II 305 outdoors, connect through air pump and installation pipeline II 305 in winter, with outdoor cold air suction to this device in, cool off indoor.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 16, and the seventh embodiment is further described in the present embodiment, the separated heat pipe intelligent energy-saving ventilation and cooling system further includes a second height adjustment bracket, a second telescopic pipe and a cross-wind mechanism 209, the second telescopic pipe is detachably and fixedly connected to an external connection pipe, the second telescopic pipe is fixedly connected to a second height adjustment, the second height adjustment is rotatably connected to the cross-wind mechanism 209, and the external connection pipe and the cross-wind mechanism 209 are connected by a second telescopic pipe; the second telescopic pipeline comprises a connecting cylinder II 401, a sliding cylinder II 403, a connecting cylinder II 404, an air injection cavity II 405 and pushing columns 406, the sliding cylinder II 403 is connected between the connecting cylinder II 401 and the connecting cylinder II 404 in a sliding manner, the air injection cavity II 405 is fixedly connected to the connecting cylinder II 404, a plurality of air injection holes are formed in the air injection cavity II 405, the air injection cavity II 405 is located in the cross air rotating ring 210, the pushing columns 406 are fixedly connected to the connecting cylinder II 401 in the connecting cylinder II 401, the connecting cylinder II 401 can be detachably and fixedly connected to the two connecting pipelines 303, and the two pushing columns 406 are respectively contacted with the two one-way mechanisms 304; the second height adjusting bracket comprises an installation barrel 407, a rotary supporting disc II 408, a thread barrel II 409 and a thread rod II 410, wherein the installation barrel 407 is rotatably connected with two thread rods II 410, the two thread rods II 410 are both connected with the thread barrel II 409 through threads, the two thread barrels II 409 are both fixedly connected with the rotary supporting disc II 408, the cross wind swivel 210 is rotatably connected with the rotary supporting disc II 408, the installation barrel 407 is fixedly connected with the connecting cylinder II 401, and the rotary supporting disc II 408 is fixedly connected with the connecting cylinder II 404; the connecting cylinder II 401 is detachably and fixedly connected to the connecting pipeline 303, the pushing column 406 pushes the one-way mechanism 304 to move downwards, the one-way mechanism 304 is enabled not to close the connecting pipeline 303 any more, the connecting pipeline 303 is communicated with the connecting cylinder II 401, cold air in the connecting pipeline 303 is introduced into the connecting cylinder II 401, the connecting cylinder II 401 introduces cold air into the cross air mechanism 209 to generate transversely rotating wind power, transversely dispersed wind power is added to the external connecting pipeline, the dispersion degree of the wind power is increased, and objects are further cooled; the wind power in the inclined direction generated by the inclined pipeline 111 pushes the transverse wind power generated by transverse dispersion to move upwards, so that the cooling wind is prevented from carrying heat to move downwards, and the heat accumulation can be prevented; rotate two threaded rods II 410 simultaneously, drive screw thread section of thick bamboo II 409 through the screw thread and move when two threaded rods II 410 rotate, and then adjust the height of crosswind mechanism 209, satisfy different user demands.

The specific implementation method nine:

in the following, the present embodiment will be described with reference to fig. 1 to 16, and the present embodiment further describes an eighth embodiment, in which the crosswind mechanism 209 includes a crosswind swivel 210, crosswind ducts 211, and inclined bodies 212, a plurality of crosswind ducts 211 are fixedly connected to the crosswind swivel 210, and a plurality of inclined bodies 212 are fixedly connected to the interior of the crosswind swivel 210.

The detailed implementation mode is ten:

the following describes the present embodiment with reference to fig. 1 to 16, and the present embodiment further describes an embodiment nine, where the cross wind mechanism 209 includes a cross wind swivel 210, a cross wind duct 211, and fan blades 213, the cross wind swivel 210 is fixedly connected with a plurality of cross wind ducts 211, and the cross wind swivel 210 is internally fixedly connected with a plurality of fan blades 213; as shown in fig. 15 and 16, the inclined body 212 and the fan blade 213 in the crosswind mechanism 209 are provided in different shapes, and may be provided in other shapes capable of generating a rotational force in the field; it should be noted that the above embodiments may be spliced with each other or all may be combined together for use.

The invention relates to a separated heat pipe intelligent energy-saving ventilation and cooling system, which has the working principle that:

according to the first embodiment illustrated in the attached drawings 1 to 2 of the specification, the device is installed in a room needing air cooling and temperature reduction through an installation bracket 101, a cooling pipeline I105 and a cooling pipeline II 109 are connected to a cold air pipeline, the cold air pipeline can cool the cooling pipeline I105 and the cooling pipeline II 109, the cooling pipeline I105 is connected with a rotary support ring 116, the cold air is introduced into the rotary support ring 116 through the cooling pipeline I105, a plurality of holes are formed in the rotary support ring 116, the cold air in the rotary support ring 116 is dispersed through the rotary support ring 116, a closed space is formed by an outer cylinder cavity 102, a rotary cavity 110 and a support low plate 112, the cold air dispersed through the rotary support ring 116 is discharged through a plurality of inclined pipelines 111 in the closed space, the inclined pipelines 111 are obliquely arranged, the cold air fed into the cooling pipeline I105 is obliquely dispersed and discharged, and the dispersed inclined wind power is used for air cooling objects needing cooling all around, the cooling pipeline II 109 provides wind power in the vertical direction, and the vertical wind power of the cooling pipeline II 109 directly cools an object on the upper part;

the arc baffle I104 and the arc baffle II 108 are both connected in the sliding cavity in a sliding mode, the cooling pipeline I105 and the cooling pipeline II 109 are respectively and fixedly connected to the arc baffle I104 and the arc baffle II 108, and the sliding positions of the arc baffle I104 and the arc baffle II 108 can be adjusted by combining the attached drawings, so that the angles of the cooling pipeline I105 and the cooling pipeline II 109 can be adjusted, different installation requirements can be met, and meanwhile, the positions of the cooling pipeline I105 and the cooling pipeline II 109 can be fixed in locking modes such as screws and the like;

according to the second embodiment illustrated in fig. 3 of the specification, a driving device for driving the driving shaft 114 to rotate is disposed on the driving shaft 114, the driving device drives the driving shaft 114 to rotate, the driving shaft 114 drives the rotating pulley 113 to rotate, the rotating pulley 113 drives the rotating cavity 110 to rotate, and further drives the inclined pipelines 111 to rotate, so that the wind power blown out by the inclined pipelines 111 is further dispersed;

according to the third embodiment illustrated in fig. 4 of the specification, the first telescoping mechanism 115 is started, the first telescoping mechanism 115 can be a hydraulic cylinder or an electric push rod, the telescoping end of the first telescoping mechanism 115 drives the rotating support ring 116 to move, and the rotating support ring 116 drives the rotating disc 117; performing a movement, rotating the disc 117; the plurality of toggle side lugs 118 are driven to move, the toggle side lugs 118 are in contact with the inclined pipeline 111 and push the inclined pipeline 111 to move, and then the inclination angle of the inclined pipeline 111 is adjusted, and the preferred telescopic mechanism I115 and the driving shaft 114 are combined for use, so that the inclined pipeline 111 can be adjusted in angle while rotating, and more use requirements are met;

the fourth embodiment is described with reference to fig. 5 to 8 in the specification, a cooling pipeline ii 109 is connected to a connecting cylinder i 205, wind power of the cooling pipeline ii 109 is introduced into a wind jet cavity i 208 through the connecting cylinder i 205, a plurality of wind jet holes are formed in the wind jet cavity i 208, vertical wind power of the cooling pipeline ii 109 is changed into transverse wind power by the wind jet cavity i 208, cold wind is blown out transversely to cool surrounding objects, meanwhile, a transverse wind mechanism 209 is further installed, wind power blown out from the wind jet cavity i 208 is blown onto an inclined body 212 or a fan blade 213, the inclined body 212 or the fan blade 213 is blown by the wind power to rotate, and meanwhile, the transverse wind pipeline 211 is driven to rotate, so that the wind power blown out transversely originally is more dispersed, and the cooling effect is further increased; meanwhile, the wind power in the inclined direction generated by the inclined pipeline 111 pushes the transverse wind power generated by transverse dispersion to move upwards, so that the cooling wind is prevented from carrying heat to move downwards, and the heat accumulation can be prevented; the two threaded rods I204 are rotated, and the two threaded rods I204 can drive the threaded cylinder I203 to move through threads when rotating, so that the height of the threaded cylinder I203 is adjusted, the height of the cross wind mechanism 209 is adjusted, and more use requirements are met;

the fifth embodiment is described with reference to fig. 9 and 11 of the specification, the cold supply pipeline i 105 and the cold supply pipeline ii 109 are both fixedly connected to the installation pipeline i 301, the length between the installation pipeline i 301 and the installation pipeline ii 305 can be adjusted, meanwhile, the position of the adjusting pipeline 302 between the installation pipeline i 301 and the installation pipeline ii 305 can also be adjusted, further, the length of the device can be adjusted, the installation pipeline ii 305 can also be connected outdoors, and in winter, the air pump is connected with the installation pipeline ii 305, so that outdoor cold air is pumped into the device, and indoor cooling is performed;

describing the sixth embodiment with reference to fig. 10, 12, 13 and 14 of the specification, the connecting cylinder ii 401 is detachably and fixedly connected to the connecting pipeline 303, the pushing column 406 pushes the one-way mechanism 304 to move downward, so that the one-way mechanism 304 does not close the connecting pipeline 303 any more, the connecting pipeline 303 is communicated with the connecting cylinder ii 401, cold air in the connecting pipeline 303 is introduced into the connecting cylinder ii 401, the connecting cylinder ii 401 introduces cold air into the cross air mechanism 209 to generate transversely-rotating wind power, transversely-dispersed wind power is added to the external connecting pipeline to increase the dispersion degree of the wind power, and further, an object is cooled; the wind power in the inclined direction generated by the inclined pipeline 111 pushes the transverse wind power generated by transverse dispersion to move upwards, so that the cooling wind is prevented from carrying heat to move downwards, and the heat accumulation can be prevented; the two threaded rods II 410 are rotated simultaneously, and the threaded cylinders II 409 are driven to move through threads when the two threaded rods II 410 rotate, so that the height of the crosswind mechanism 209 is adjusted, and different use requirements are met;

as shown in fig. 15 and 16, the inclined body 212 and the fan blade 213 in the crosswind mechanism 209 are provided in different shapes, and may be provided in other shapes capable of generating a rotational force in the field; it should be noted that the above embodiments may be spliced with each other or all may be combined together for use.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (9)

1. The utility model provides an energy-conserving ventilation cooling system of disconnect-type heat pipe intelligence, includes urceolus cavity (102), cooling pipeline I (105), cooling pipeline II (109), rotates cavity (110), slope pipeline (111), supports low dish (112) and intermittent type spheroid (119), its characterized in that: the cooling pipeline I (105) and the cooling pipeline II (109) are inserted into the outer cylinder cavity (102), the outer cylinder cavity (102) is connected with a rotating cavity (110) in a rotating mode, intermittent spheres (119) are arranged on the rotating cavity (110) in an intermittent matching mode, at least one intermittent sphere (119) is arranged, each intermittent sphere (119) is fixedly connected with an inclined pipeline (111), a support low plate (112) is fixedly connected onto the cooling pipeline II (109), the support low plate (112) is connected onto the rotating cavity (110) in a rotating mode, the cooling pipeline II (109) penetrates through the support low plate (112), the cooling pipeline I (105) generates cold air in an inclined direction through the inclined pipeline (111), and the cooling pipeline II (109) generates cold air in a vertical direction;

energy-conserving ventilation cooling system of disconnect-type heat pipe intelligence still includes telescopic machanism I (115), rotate and prop ring (116), rolling disc (117) and stir side ear (118), telescopic machanism I (115) fixed connection is in urceolus cavity (102), the flexible end fixedly connected with of telescopic machanism I (115) rotates and props ring (116), it is connected with rolling disc (117) to rotate on propping ring (116), fixedly connected with stirs side ear (118) on rolling disc (117), stir side ear (118) and be provided with one at least, every is stirred and all is provided with the waist hole on side ear (118), insert respectively in a plurality of waist holes a plurality of slope pipelines (111).

2. The intelligent energy-saving ventilation and cooling system with separated heat pipes of claim 1, wherein: the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises an installation support (101), an inner cylinder wall (103), an arc baffle I (104) and an arc baffle II (108), wherein an outer cylinder cavity (102) is fixedly connected onto the installation support (101), the inner cylinder wall (103) of the outer cylinder cavity (102) is fixedly connected inside, a sliding cavity is formed between the inner cylinder wall (103) and the outer cylinder cavity (102), the arc baffle I (104) and the arc baffle II (108) are connected in the sliding cavity in a sliding mode, and a cooling pipeline I (105) and a cooling pipeline II (109) are respectively and fixedly connected onto the arc baffle I (104) and the arc baffle II (108).

3. The intelligent energy-saving ventilation and cooling system with separated heat pipes as claimed in claim 2, wherein: the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a wind dissipation ring (106) and an installation support ring (107), the wind dissipation ring (106) is fixedly connected with the cooling pipeline I (105), the wind dissipation ring (106) is in clearance fit with the installation support ring (107), and the installation support ring (107) is fixedly connected to the inner cylinder wall (103).

4. The intelligent energy-saving ventilation and cooling system with separated heat pipes as claimed in claim 2, wherein: the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises a rotating belt wheel (113) and a driving shaft (114), the rotating belt wheel (113) is fixedly connected to the rotating cavity (110), the driving shaft (114) is rotatably connected to the mounting support (101), the driving shaft (114) is in transmission connection with the rotating belt wheel (113), and a driving device for driving the driving shaft (114) to rotate is arranged on the driving shaft (114).

5. The intelligent energy-saving ventilation and cooling system with separated heat pipes of claim 1, wherein: energy-conserving ventilation cooling system of disconnect-type heat pipe intelligence still includes first height adjustment support, first flexible pipeline and crosswind mechanism (209), first height adjustment support fixed connection is on supporting low dish (112), crosswind mechanism (209) rotate to be connected on first height adjustment support, connect through first flexible pipeline between cooling pipeline II (109) and crosswind mechanism (209), crosswind mechanism (209) are the wind-force dispersion of the vertical direction of cooling pipeline II (109) for horizontal wind-force.

6. The intelligent energy-saving ventilation and cooling system with separated heat pipes of claim 1, wherein: the separated heat pipe intelligent energy-saving ventilation and cooling system further comprises an external connecting pipeline, and the external connecting pipeline is connected to the cooling pipeline I (105) and the cooling pipeline II (109).

7. The intelligent energy-saving ventilation and cooling system with separated heat pipes of claim 6, wherein: the separating heat pipe intelligent energy-saving ventilation and cooling system further comprises a second height adjusting support, a second telescopic pipeline and a transverse air mechanism (209), the second telescopic pipeline can be detachably connected with the external connecting pipeline in a fixed mode, the second telescopic pipeline is fixedly connected with a second height adjusting mode, the second height adjusting mode is rotatably connected with the transverse air mechanism (209), and the external connecting pipeline and the transverse air mechanism (209) are connected through the second telescopic pipeline.

8. The separated heat pipe intelligent energy-saving ventilation and cooling system according to claim 5 or 7, wherein: the crosswind mechanism (209) comprises a crosswind swivel (210), crosswind pipelines (211) and a plurality of inclined bodies (212), wherein the crosswind swivel (210) is fixedly connected with the crosswind pipelines (211), and the crosswind swivel (210) is internally fixedly connected with the inclined bodies (212).

9. The separated heat pipe intelligent energy-saving ventilation and cooling system according to claim 5 or 7, wherein: the crosswind mechanism (209) comprises a crosswind swivel (210), crosswind pipelines (211) and fan blades (213), wherein the crosswind swivel (210) is fixedly connected with the crosswind pipelines (211), and the crosswind swivel (210) is internally fixedly connected with the fan blades (213).

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