CN114322108B - Energy-saving heating ventilation air conditioning system in large building - Google Patents

Abstract

The application relates to an energy-saving heating ventilation air conditioning system in a large building, which comprises a first pipe body, a second pipe body and a third pipe body, wherein the first pipe body, the second pipe body and the third pipe body are sequentially arranged and are detachably connected through bolts, a mounting through groove is formed in the top of the second pipe body, a supporting piece is detachably inserted into the inner side of the mounting through groove, and a wind driven structure is mounted on the supporting piece, wherein the supporting piece comprises a bearing plate, a vertical plate integrally formed with the bearing plate is mounted on the vertical plate, and the wind driven structure is mounted on the vertical plate.

Description

Energy-saving heating ventilation air conditioning system in large building

Technical Field

The application relates to an energy-saving heating, ventilation and air conditioning system, in particular to an energy-saving heating, ventilation and air conditioning system in a large building.

Background

In a large building, the warm through pipe is not provided with any structure on the inner side, so that substances such as dust generated by aging are not avoided in the long-time use pipeline, the pipeline is discharged when warm air is discharged, and falls down due to the vertical arrangement of the pipeline, so that dust and the like still exist at the warm air outlet after repeated cleaning;

an energy-saving heating, ventilation and air conditioning system in a large building is provided for solving the problems.

Disclosure of Invention

The application aims to provide an energy-saving heating, ventilation and air conditioning system in a large building, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present application provides the following technical solutions:

an energy efficient hvac system in a large building, the energy efficient hvac system in a large building comprising:

the first pipe body, the second pipe body and the third pipe body are arranged in sequence and detachably connected through bolts:

the installation through groove is formed in the top of the second pipe body, a supporting piece is detachably inserted into the inner side of the installation through groove, and a wind power driving structure is arranged on the supporting piece;

wherein, support piece includes the board of accepting, accept the board install with it integrated into one piece's riser, wind-force drive structure installs on the riser:

the sealing plate, the sealing plate articulate in first body inboard, the sealing plate is in through installing the inboard push structure of second body is connected wind-force drive structure, just the sealing plate still with install the block structure cooperation at first body top.

As a further scheme of the application: the wind power driving structure comprises a transmission shaft penetrating through the vertical plate and rotationally connected with the vertical plate, the transmission shaft is connected with the pushing structure, a transmission frame is arranged at one end of the transmission shaft in a pipeline mode, a plurality of force-generating blades are circumferentially distributed on the transmission frame, a plurality of groups of bristles are arranged on one side, away from the force-generating blades, of the transmission frame, and the bristles are in butt joint with the vertical plate.

As still further aspects of the application: the pushing structure comprises a screw rod rotatably arranged at the inner side of the second pipe body, a threaded sleeve in threaded fit with the screw rod is sleeved at the outer side of the screw rod, the threaded sleeve is hinged with the sealing plate, and the screw rod is connected with the transmission shaft through a transmission belt;

and one end of the screw rod, which is far away from the threaded sleeve, is also provided with an elastic structure.

As a further scheme of the application: the elastic structure comprises a spring sleeve fixedly arranged on the inner side of the second pipe body, a sliding rod is arranged on the inner side of the spring sleeve in a sliding manner, and a spring is arranged between the spring sleeve and the sliding rod;

the upper part of the sliding rod is fixedly provided with a rack plate, the rack plate is meshed with a gear fixed at the tail end of the screw rod, and one side of the rack plate is also provided with a guide structure.

As still further aspects of the application: the guide structure comprises a limit sliding block fixedly arranged on one side of the rack plate, and the limit sliding block is matched with a limit sliding groove arranged on the inner wall of the second pipe body in a sliding manner;

the limiting sliding block and the limiting sliding groove are both T-shaped.

As still further aspects of the application: the clamping structure comprises two limiting blocks fixed on the sealing plate, and the two limiting blocks are matched with a clamping groove arranged at the top of the first pipe body;

the limiting block is elastically arranged, and a clamping block is arranged on one side of the limiting block;

and the first pipe body is also provided with an unlocking structure matched with the limiting block, and the unlocking structure is connected with the control structure.

As still further aspects of the application: the unlocking structure comprises two electric telescopic rods which are symmetrically and fixedly arranged on the first pipe body, and the two electric telescopic rods are connected with the control structure through leads;

wherein, two the movable rod tip symmetry of electric telescopic handle is provided with the inclined plane.

As still further aspects of the application: the control structure comprises a wireless control switch fixedly arranged on the first pipe body, and the wireless control switch is connected with the two electric telescopic rods through a wire.

Compared with the prior art, the application has the beneficial effects that: the flow of the warm air pipe drives the wind driven structure to work, the pushing structure pushes the sealing plate to overturn when the wind driven structure works so that the first pipe body, the second pipe body and the third pipe body are in a communication state, warm air can be normally discharged, and the sealing plate is matched with the clamping structure to be locked when the sealing plate overturns to the end of a stroke, so that the warm air can be continuously discharged, the sealing plate can not be driven to move to the end of the stroke by the normal warm air flowing through the wind driven structure and the pushing structure, the sealing plate is in a swinging state, the discharge flow rate of the warm air is increased, the power of the wind driven structure can be driven to be increased, and the sealing plate can be driven to overturn to the end of the stroke and be matched with the clamping structure to be locked;

the air conditioner comprises a wind power driving structure, a support piece, a screen plate, a filter plate and a filter plate, wherein the air conditioner is characterized in that the screen plate is arranged on the support piece when the wind power driving structure works, dust, filterable harmful substances and the like in warm air can be filtered through the support piece, so that the quality of the discharged warm air is ensured;

the side of the sealing plate far away from the hinge part is made of deformable materials;

the application can filter the discharged warm air while controlling the closing of the warm air pipeline, and does not need active driving equipment in the process, and the device has a relatively simple structure so as to reduce the use cost and the production cost.

Drawings

Fig. 1 is a schematic structural diagram of an energy-saving hvac system in a large building.

Fig. 2 is a schematic three-dimensional structure of an energy-saving heating, ventilation and air conditioning system in a large building.

Fig. 3 is a schematic view of the structure of the energy-saving hvac system in a large building at another angle of fig. 2.

Fig. 4 is a cross-sectional view of fig. 2 in an energy efficient hvac system in a large building.

Fig. 5 is a schematic view of the energy-saving hvac system in a large building in the further direction of fig. 4.

Fig. 6 is an exploded view of fig. 2 in an energy efficient hvac system in a large building.

Fig. 7 is a schematic view of the structure of the energy-saving hvac system in a large building at another angle of fig. 6.

Fig. 8 is an enlarged view of a partial structure of the energy-saving hvac system in a large building at fig. 6A.

In the figure: 1-first body, 2-second body, 3-third body, 4-support piece, 5-block groove, 6-electric telescopic rod, 7-wire, 8-wireless control switch, 9-stopper, 10-closing plate, 11-power blade, 12-drive frame, 13-drive belt, 14-drive shaft, 15-brush hair, 16-spring sleeve, 17-gear, 18-rack board, 19-lead screw, 20-screw sleeve.

Description of the embodiments

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In addition, an element in the present disclosure may be referred to as being "fixed" or "disposed" on another element or being directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Referring to fig. 1-8, in an embodiment of the present application, an energy-saving heating, ventilation and air conditioning system in a large building includes:

the first pipe body 1, the second pipe body 2 and the third pipe body 3 are sequentially arranged and detachably connected through bolts:

the installation through groove is formed in the top of the second pipe body 2, a supporting piece 4 is detachably inserted into the inner side of the installation through groove, and a wind power driving structure is arranged on the supporting piece 4;

wherein, support 4 includes the board of accepting, accept the board install with it integrated into one piece's riser, wind-force drive structure installs on the riser:

the sealing plate 10, the sealing plate 10 articulates in the inboard of first body 1, the sealing plate 10 is in through installing the inboard push structure of second body 2 is connected wind-force drive structure, just the sealing plate 10 still with install the block structure cooperation at first body 1 top.

In the embodiment of the application, the wind driven structure is driven to work through the flow of the warm air pipe, when the wind driven structure works, the pushing structure pushes the sealing plate 10 to turn over so that the first pipe body 1, the second pipe body 2 and the third pipe body 3 are in a communicated state, the warm air can be normally discharged, when the sealing plate 10 turns over to the end of the stroke, the sealing plate 10 is matched with the clamping structure to be locked, so that the discharge of the warm air can be continuously carried out, the sealing plate 10 is driven to the end of the stroke by the wind driven structure and the pushing structure to be not held by the wind under the normal warm air flow, the sealing plate 10 is in a swinging state, the discharge of the warm air is not influenced, and the discharge flow rate of the warm air is increased so that the power of the wind driven structure is driven to be larger, and the sealing plate 10 can be driven to turn over to the end of the stroke and be matched with the clamping structure to be locked;

the air conditioner comprises a wind power driving structure, a support piece 4, a screen plate, a filter plate and a filter plate, wherein the air conditioner is further used for cleaning the panel when the wind power driving structure works, dust, filterable harmful substances and the like in warm air can be filtered through the support piece 4, so that the quality of the discharged warm air is ensured;

it should be noted that the side of the sealing plate 10 away from the hinge is made of deformable material;

the application can filter the discharged warm air while controlling the closing of the warm air pipeline, and does not need active driving equipment in the process, and the device has a relatively simple structure so as to reduce the use cost and the production cost.

In this embodiment of the present application, the wind-driven structure includes a driving shaft 14 penetrating through the riser and rotationally connected with the riser, the driving shaft 14 is connected with the pushing structure, a driving frame 12 is installed at one end of the driving shaft 14 in a pipeline, a plurality of force-generating blades 11 are circumferentially distributed on the driving frame 12, a plurality of groups of bristles 15 are installed at one side of the driving frame 12 far from the force-generating blades 11, and the bristles 15 are abutted to the riser.

In the embodiment of the application, when warm air is discharged, the center of the warm air is opposite to the transmission frame 12, the transmission frame 12 disperses the separated circumference of wind power to drive the force-generating blades 11 to rotate, so that the force-generating blades 11 drive the transmission frame 12 to rotate, and the transmission frame 12 drives the transmission shaft 14 to drive the pushing structure to work;

wherein, the transmission frame 12 rotates to discharge and convey the corresponding warm air, and the faster the flow speed of the discharge is, the faster the rotation speed of the transmission frame 12 is, and the larger the torque is.

In the embodiment of the application, the pushing structure comprises a screw rod 19 rotatably arranged at the inner side of the second pipe body 2, a threaded sleeve 20 in threaded fit with the screw rod 19 is sleeved at the outer side of the screw rod 19, the threaded sleeve 20 is hinged with the sealing plate 10, and the screw rod 19 is connected with the transmission shaft 14 through a transmission belt 13;

wherein, the end of the screw rod 19 far away from the threaded sleeve 20 is also provided with an elastic structure.

In the embodiment of the application, when the transmission shaft 14 rotates, the transmission shaft 14 drives the screw rod 19 to rotate, and when the screw rod 19 rotates, the elastic structure is driven to work, and meanwhile, the sealing plate 10 is driven to horizontally move, so that the screw rod 19 is pushed to turn over by the threaded sleeve 20;

under the clamping of the elastic structure, the screw 19 is limited in rotation and stores a certain reaction force so that it can be closed by the reaction force when the warm air stops being delivered or the flow rate is small.

In the embodiment of the application, the elastic structure package is fixedly arranged on the spring sleeve 16 at the inner side of the second pipe body 2, a sliding rod is arranged at the inner side of the spring sleeve 16 in a sliding manner, and a spring is arranged between the spring sleeve 16 and the sliding rod;

the upper part of the sliding rod is fixedly provided with a rack plate 18, the rack plate 18 is meshed with a gear 17 fixed at the tail end of the screw rod 19, and one side of the rack plate 18 is also provided with a guide structure.

In the embodiment of the application, the gear 17 is driven to rotate when the screw rod 19 rotates, so that the rack plate 18 is driven to vertically move, and the slide bar is driven to vertically move through the rack plate 18, so that a certain elastic potential energy is reserved through the compression or the extension of the spring by the slide bar;

when the warm air stops being discharged, the gear 17 and the screw rod 19 can be driven to rotate in the opposite direction by releasing the elastic potential energy of the spring.

In the embodiment of the application, the guiding structure comprises a limit sliding block fixedly arranged on one side of the rack plate 18, and the limit sliding block is matched with a limit sliding groove arranged on the inner wall of the second pipe body 2 in a sliding way;

the limit sliding block and the limit sliding groove are both in a T shape (not shown in the figure).

In the embodiment of the application, when the rack plate 18 moves vertically, the limit sliding block is driven to slide vertically on the inner side of the limit sliding groove, so that friction force is reduced to enable the movement to be smoother, and the limit guiding function can be achieved on the rack plate 18;

of course, the guiding manner set forth in the present embodiment is not limited, and the corresponding adjustment can be performed according to the actual requirement, which is not specifically limited by the present application.

In the embodiment of the present application, the clamping structure includes two limiting blocks 9 fixed on the sealing plate 10, and the two limiting blocks 9 are matched with the clamping groove 5 arranged at the top of the first pipe body 1;

the limiting block 9 is elastically arranged, and a clamping block is arranged on one side of the limiting block 9;

and an unlocking structure matched with the limiting block 9 is further arranged on the first pipe body 1, and the unlocking structure is connected with the control structure.

In the embodiment of the application, when the limiting block 9 is overturned to the end of the stroke, the limiting block 9 is inserted into the inner side of the clamping groove 5 through the sealing plate 10 and is bent to be clamped with the first pipe body 1 through the clamping block, so that the limiting block 9 is in a locking state;

therefore, the warm air is not constrained under the maximum flow velocity, and is matched with the unlocking structure without manual unlocking, so that the warm air is very convenient to use.

In the embodiment of the application, the unlocking structure comprises two electric telescopic rods 6 symmetrically and fixedly arranged on the first pipe body 1, and the two electric telescopic rods 6 are connected with the control structure through leads 7;

wherein, the movable rod ends of the two electric telescopic rods 6 are symmetrically provided with inclined surfaces.

In the embodiment of the application, the two electric telescopic rods 6 are controlled to work simultaneously through the control structure so as to extend out through the movable rod at the movable end, so that the clamping block is pushed to be limited through the inclined surface, and the clamping block is unlocked;

after unlocking is completed, the movable rod of the electric telescopic rod 6 is reset to be used next time.

In the embodiment of the application, the control structure comprises a wireless control switch 8 fixedly arranged on the first pipe body 1, and the wireless control switch 8 is connected with the two electric telescopic rods 6 through a lead 7.

In the embodiment of the application, the wireless control switch 8 is a very mature prior art, so that the two electric telescopic rods 6 are driven to synchronously work through the wireless control switch 8;

the wireless control switch 8 in the application adopts one hundred million Baite/EBYTE, and the specific model is as follows: c01-04, of course, to reduce the production cost, the wireless control may be replaced by a wired control, which is specifically limited by the present application.

It will be evident to those skilled in the art that the application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (6)

1. An energy-saving heating, ventilation and air conditioning system in a large building, characterized in that the energy-saving heating, ventilation and air conditioning system in the large building comprises:

the novel pipe comprises a first pipe body (1), a second pipe body (2) and a third pipe body (3), wherein the first pipe body (1), the second pipe body (2) and the third pipe body (3) are sequentially arranged and detachably connected through bolts:

the installation through groove is formed in the top of the second pipe body (2), a supporting piece (4) is detachably inserted into the inner side of the installation through groove, and a wind power driving structure is arranged on the supporting piece (4);

wherein, support piece (4) are including accepting the board, accept the board install with it integrated into one piece's riser, wind-force drive structure installs on the riser:

the sealing plate (10) is hinged to the inner side of the first pipe body (1), the sealing plate (10) is connected with the wind power driving structure through a pushing structure arranged on the inner side of the second pipe body (2), and the sealing plate (10) is matched with a clamping structure arranged on the top of the first pipe body (1);

the wind power driving structure comprises a transmission shaft (14) penetrating through the vertical plate and rotationally connected with the vertical plate, the transmission shaft (14) is connected with the pushing structure, a transmission frame (12) is arranged at one end of the transmission shaft (14) in a pipeline, a plurality of force-generating blades (11) are circumferentially distributed on the transmission frame (12), a plurality of groups of bristles (15) are arranged on one side, far away from the force-generating blades (11), of the transmission frame (12), and the bristles (15) are abutted with the vertical plate;

the pushing structure comprises a screw rod (19) rotatably arranged at the inner side of the second pipe body (2), a threaded sleeve (20) in threaded fit with the screw rod (19) is sleeved at the outer side of the screw rod (19), the threaded sleeve (20) is hinged with the sealing plate (10), and the screw rod (19) is connected with the transmission shaft (14) through a transmission belt (13);

wherein, the screw rod (19) is far away from the one end of screw sleeve (20) still installs elastic structure.

2. An energy-saving heating, ventilation and air conditioning system in a large building according to claim 1, characterized in that the elastic structure comprises a spring sleeve (16) fixedly installed inside the second pipe body (2), a sliding rod is slidingly installed inside the spring sleeve (16), and a spring is installed between the spring sleeve (16) and the sliding rod;

the upper part of the sliding rod is fixedly provided with a rack plate (18), the rack plate (18) is meshed with a gear (17) fixed at the tail end of the screw rod (19), and one side of the rack plate (18) is also provided with a guide structure.

3. The energy-saving heating, ventilation and air conditioning system in a large building according to claim 2, wherein the guiding structure comprises a limit slide block fixedly arranged on one side of the rack plate (18), and the limit slide block is matched with a limit slide groove arranged on the inner wall of the second pipe body (2) in a sliding manner;

the limiting sliding block and the limiting sliding groove are both T-shaped.

4. An energy-saving heating, ventilation and air conditioning system in a large building according to claim 1, characterized in that the clamping structure comprises two limiting blocks (9) fixed on the sealing plate (10), wherein the two limiting blocks (9) are matched with a clamping groove (5) arranged at the top of the first pipe body (1);

the limiting block (9) is elastically arranged, and a clamping block is arranged on one side of the limiting block (9);

and an unlocking structure matched with the limiting block (9) is further arranged on the first pipe body (1), and the unlocking structure is connected with the control structure.

5. Energy-saving hvac system in large buildings according to claim 4, characterized in that the unlocking structure comprises two electric telescopic rods (6) symmetrically and fixedly mounted on the first pipe body (1), both electric telescopic rods (6) being connected with the control structure by means of wires (7);

wherein, the movable rod ends of the two electric telescopic rods (6) are symmetrically provided with inclined planes.

6. Energy-efficient hvac system in a large building according to claim 5, characterized in that the control structure comprises a wireless control switch (8) fixedly mounted on the first pipe body (1), the wireless control switch (8) being connected to two of the electric telescopic rods (6) by means of wires (7).