CN212930349U - Energy-conserving ventilation structure for architectural design - Google Patents

Abstract

The utility model relates to an energy-conserving ventilation technical field of building discloses an energy-conserving ventilation structure for architectural design, including blast pipe and intake pipe, still include synchronous energy-conserving ventilation mechanism of taking a breath, the bottom of blast pipe is connected with the intake pipe, blast pipe and intake pipe all are connected with synchronous energy-conserving ventilation mechanism of taking a breath, synchronous energy-conserving ventilation mechanism of taking a breath includes gear motor, output pivot, installation rotary drum, collection aerofoil, auxiliary bearing, support frame, driven shaft, helps dynamic bearing, water conservancy diversion fan, active carbon filter frame and backflow board, gear motor's positive center through-hole department swing joint has the output pivot. The utility model discloses can single rotatory function mechanism accomplish simultaneously to the exhaust of building with admit air work and to exhaust gas's filtration work, the mode of avoiding the ventilation of current mechanicalness can set up the air guide structure respectively in exhaust and the department of admitting air and accomplish exhaust and the work of admitting air and cause the problem of energy loss.

Description

Energy-conserving ventilation structure for architectural design

Technical Field

The utility model relates to an energy-conserving ventilation technical field of building specifically is an energy-conserving ventilation structure for architectural design.

Background

The building ventilation is divided into natural ventilation and mechanical ventilation, which means that dirty air in a building is directly or after being purified, discharged to the outside, and fresh air is supplemented, so that the indoor air environment is kept in accordance with the sanitary standard. The purpose is as follows: firstly, the indoor pollutants are removed, secondly, the heat comfort of indoor personnel is ensured, and thirdly, the requirement of the indoor personnel on fresh air is met. For buildings with weak natural ventilation, the ventilation and air exchange work of the indoor space needs to be completed through a mechanical ventilation structure, the mechanical ventilation mainly comprises two parts of active discharge of indoor air and active discharge of outdoor fresh air, and air guide structures are generally arranged at the exhaust and intake positions respectively to complete the ventilation and air exchange work, so that the energy consumption is increased greatly in an intangible manner.

SUMMERY OF THE UTILITY MODEL

The utility model provides an energy-conserving ventilation structure for architectural design, this energy-conserving ventilation structure for architectural design, the mode of having solved the ventilation of current mechanicalness generally can set up the air guide structure respectively in exhaust and the department of admitting air and accomplish exhaust and work of admitting air, among the intangible greatly increased energy resource consumption's problem.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an energy-saving ventilation structure for building design comprises an exhaust pipe, an air inlet pipe and a synchronous air-changing energy-saving ventilation mechanism, wherein the bottom of the exhaust pipe is connected with the air inlet pipe;

the synchronous ventilation energy-saving ventilation mechanism comprises a speed reducing motor, an output rotating shaft, an installation rotating drum, an air collecting plate, an auxiliary bearing, a supporting frame, a driven rotating shaft, an auxiliary bearing, a flow guiding fan, an active carbon filter frame and a return plate;

an output rotating shaft is movably connected with the through hole in the front surface of the speed reducing motor, a mounting rotating drum is fixedly arranged on the outer surface of the side part of the output rotating shaft, the outer surface of the side part of the mounting rotary drum is fixedly provided with a wind collecting plate, the back surface of the output rotary shaft is fixedly connected with an auxiliary bearing, the auxiliary bearing is fixedly arranged on one side of the front surface of the inner cavity arranged at the joint of the exhaust pipe and the air inlet pipe, the top and the bottom of the support frame are fixedly connected with the top and the bottom of the inner wall of the exhaust pipe, an auxiliary bearing is fixedly arranged at the position of the middle part of the side edge of the support frame, which is provided with a hole, the inner cavity of the power-assisted bearing is movably connected with a driven rotating shaft, one end of the driven rotating shaft is provided with a flow guide fan, the other end fixed mounting of driven spindle has the active carbon filter frame, one section top and the bottom fixed mounting of inner wall of blast pipe have the board of flow returning, the board setting of flow returning is in one side of active carbon filter frame.

Preferably, the output rotating shaft is movably attached and connected with a hole formed in the back of the connection part of the exhaust pipe and the air inlet pipe.

Preferably, a movable hinge is fixedly mounted at the top of one side of the air inlet pipe, and a closing plate is fixedly connected to one side of the movable hinge.

Preferably, one side of the closing plate is movably connected with an opening at one side of the air inlet pipe.

Preferably, the bottom end of the closing plate is fixedly provided with an inserting rod, and one side of the bottom of the air inlet pipe is fixedly provided with an inserting groove plate.

Preferably, the outer surface of the side part of the insertion rod is movably inserted into the inner cavity of the notch formed in one side of the insertion groove plate.

Borrow by above-mentioned technical scheme, the utility model provides an energy-conserving ventilation structure for architectural design. The method at least has the following beneficial effects:

(1) the energy-saving ventilation structure for building design utilizes a synchronous ventilation energy-saving ventilation mechanism, under the condition of needing ventilation work, a speed reducing motor is started, an output rotating shaft rotates to drive a wind collecting plate fixedly installed on the outer surface of the side part of an installation rotating drum to rotate, an auxiliary bearing provides an auxiliary action for the rotation activity of the wind collecting plate, the rotation mode of the wind collecting plate is anticlockwise rotation, the wind collecting plate is simultaneously arranged in the inner cavities of an exhaust pipe and an air inlet pipe and is positioned at the joint of the exhaust pipe and the air inlet pipe, the wind collecting plate in the rotation state can exhaust indoor air to the outdoor through the exhaust pipe, meanwhile, outdoor fresh air is introduced into the indoor through the air inlet pipe, the exhaust and air inlet work of a building is simultaneously completed through single rotation activity, the exhausted outdoor air generally needs to be filtered and then reaches the emission standard to be exhausted, and the flowing air of the exhaust pipe flows through a flow guide fan, the water conservancy diversion fan receives the wind-force influence and produces autonomic rotation for the activity strong point with the help bearing through driven spindle, and driven spindle follows to rotate the active carbon filter frame that drives its other end and rotates, carries out filtration treatment to the gas that will discharge promptly, and from the partial gas of active carbon filter frame top and bottom omission, through the bounce that returns the flow board bump once more to rotatory active carbon filter frame on, the guarantee is to exhaust gas filtration work's integrality.

(2) This energy-conserving ventilation structure is used in architectural design meets when the building and need not under the condition of admitting air only to exhaust, through accomplishing the grafting of closing plate bottom peg graft pole and intake pipe bottom one side grafting frid inner chamber, can seal the opening of intake pipe one side with the closing plate, prevents going on of external air current and only carries out solitary exhaust filtration work.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application:

fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a side cross-sectional view of the junction of the exhaust pipe and the intake pipe of FIG. 1 in accordance with the present invention;

fig. 3 is an enlarged view of a portion a in fig. 1 according to the present invention.

In the figure: 1, an exhaust pipe, 2 an air inlet pipe, 3 a synchronous ventilation energy-saving ventilation mechanism, 31 a speed reducing motor, 32 an output rotating shaft, 33 an installation rotating cylinder, 34 an air collecting plate, 35 an auxiliary bearing, 36 a supporting frame, 37 a driven rotating shaft, 38 an auxiliary bearing, 39 a flow guiding fan, 310 an activated carbon filter frame and 311 a flow returning plate;

4 movable hinges, 5 closing plates, 6 inserting rods and 7 inserting groove plates.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, the present invention provides a technical solution: an energy-saving ventilation structure for building design comprises an exhaust pipe 1, an air inlet pipe 2 and a synchronous air-changing energy-saving ventilation mechanism 3, wherein the bottom of the exhaust pipe 1 is connected with the air inlet pipe 2, and the exhaust pipe 1 and the air inlet pipe 2 are both connected with the synchronous air-changing energy-saving ventilation mechanism 3;

the synchronous ventilation energy-saving ventilation mechanism 3 comprises a speed reducing motor 31, an output rotating shaft 32, a mounting rotating drum 33, an air collecting plate 34, an auxiliary bearing 35, a support frame 36, a driven rotating shaft 37, an auxiliary bearing 38, a flow guiding fan 39, an activated carbon filter frame 310 and a return plate 311;

the front center through hole of the speed reducing motor 31 is movably connected with an output rotating shaft 32, the lateral outer surface of the output rotating shaft 32 is fixedly provided with an installation rotating cylinder 33, the lateral outer surface of the installation rotating cylinder 33 is fixedly provided with a wind collecting plate 34, the back of the output rotating shaft 32 is fixedly connected with an auxiliary bearing 35, the auxiliary bearing 35 is fixedly arranged at one side of the front surface of an inner cavity formed at the joint of the exhaust pipe 1 and the air inlet pipe 2, the top and the bottom of a support frame 36 are fixedly connected with the top and the bottom of the inner wall of the exhaust pipe 1, a hole is formed in the middle of the side edge of the support frame 36, an auxiliary bearing 38 is fixedly arranged in the inner cavity of the auxiliary bearing 38, a driven rotating shaft 37 is movably connected with the inner cavity of the driven rotating shaft 37, a guide fan 39 is arranged at one end of the driven rotating shaft 37, an activated carbon filter frame 310 is.

The output rotating shaft 32 is movably jointed and connected with a hole arranged on the back of the joint of the exhaust pipe 1 and the air inlet pipe 2.

One side top fixed mounting of intake pipe 2 has movable hinge 4, and one side fixedly connected with closing plate 5 of movable hinge 4, and one side top of intake pipe 2 provides the activity support for closing plate 5 through movable hinge 4.

One side of the closing plate 5 is movably connected with an opening at one side of the air inlet pipe 2.

The bottom end of the closing plate 5 is fixedly provided with an inserting rod 6, and one side of the bottom of the air inlet pipe 2 is fixedly provided with an inserting groove plate 7.

The outer surface of the side part of the insertion rod 6 is movably inserted into the inner cavity of the notch formed on one side of the insertion groove plate 7.

When the building meets the condition that only exhaust is needed and air inlet is not needed, the opening on one side of the air inlet pipe 2 can be closed by the closing plate 5 by completing the insertion of the inner cavities of the inserting rod 6 at the bottom of the closing plate 5 and the inserting groove plate 7 at one side of the bottom of the air inlet pipe 2, and the outside air flow is prevented from being carried out and only independent exhaust filtering work is carried out.

When in use, under the condition that ventilation work is needed, the speed reducing motor 31 is started, the output rotating shaft 32 rotates to drive the wind collecting plate 34 fixedly installed on the outer surface of the side part of the installation rotating drum 33 to rotate, the auxiliary bearing 35 provides auxiliary action for the rotation movement of the wind collecting plate 34, the rotation mode of the wind collecting plate 34 is anticlockwise rotation, because the wind collecting plate 34 is simultaneously arranged in the inner cavities of the exhaust pipe 1 and the air inlet pipe 2 and is positioned at the joint of the exhaust pipe 1 and the air inlet pipe 2, the wind collecting plate 34 in the rotation state can discharge indoor air to the outdoor through the exhaust pipe 1, meanwhile, outdoor fresh air is introduced into the indoor through the air inlet pipe 2, the exhaust and air inlet work of a building is simultaneously completed through single rotation movement, the gas discharged to the outdoor generally reaches the emission standard after being filtered, and when the flowing gas of the exhaust pipe 1 flows through the flow guide fan 39, the diversion fan 39 is influenced by wind power and automatically rotates by taking the auxiliary bearing 38 as a movable supporting point through the driven rotating shaft 37, the driven rotating shaft 37 rotates along with the rotation to drive the activated carbon filter frame 310 at the other end to rotate, the exhausted gas is filtered, and partial gas left from the top and the bottom of the activated carbon filter frame 310 collides with the rotating activated carbon filter frame 310 again through the rebound force of the backflow plate 311, so that the integrity of the exhaust gas filtering work is guaranteed.

It is right above the utility model provides an energy-conserving ventilation structure for architectural design has carried out the detailed introduction. The utility model discloses it is right to have used specific individual example the utility model discloses a principle and implementation have been elucidated, and the explanation of above embodiment is only used for helping understanding the utility model discloses a method and core thought thereof. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (6)

1. The utility model provides an energy-conserving ventilation structure for architectural design, includes blast pipe (1) and intake pipe (2), its characterized in that: the energy-saving ventilation device is characterized by further comprising a synchronous ventilation energy-saving ventilation mechanism (3), wherein the bottom of the exhaust pipe (1) is connected with an air inlet pipe (2), and the exhaust pipe (1) and the air inlet pipe (2) are both connected with the synchronous ventilation energy-saving ventilation mechanism (3);

the synchronous ventilation energy-saving ventilation mechanism (3) comprises a speed reducing motor (31), an output rotating shaft (32), a mounting rotating drum (33), a wind collecting plate (34), an auxiliary bearing (35), a support frame (36), a driven rotating shaft (37), an auxiliary bearing (38), a flow guide fan (39), an active carbon filter frame (310) and a return plate (311);

the front center through hole of the speed reducing motor (31) is movably connected with an output rotating shaft (32), the outer surface of the side part of the output rotating shaft (32) is fixedly provided with an installation rotating drum (33), the outer surface of the side part of the installation rotating drum (33) is fixedly provided with a wind collecting plate (34), the back surface of the output rotating shaft (32) is fixedly connected with an auxiliary bearing (35), the auxiliary bearing (35) is fixedly arranged on one side of the front surface of an inner cavity formed at the joint of an exhaust pipe (1) and an intake pipe (2), the top and the bottom of a support frame (36) are fixedly connected with the top and the bottom of the inner wall of the exhaust pipe (1), a hole is formed in the middle position of the side edge of the support frame (36) and is fixedly provided with an auxiliary bearing (38), the inner cavity of the auxiliary bearing (38) is movably connected with a driven rotating shaft (37, the other end fixed mounting of driven spindle (37) has activated carbon to strain frame (310), one section top and the bottom fixed mounting of inner wall of blast pipe (1) have backflow board (311), backflow board (311) set up the one side that strains frame (310) at activated carbon.

2. An energy-saving ventilating structure for architectural design according to claim 1, wherein: the output rotating shaft (32) is movably connected with a hole formed in the back of the joint of the exhaust pipe (1) and the air inlet pipe (2) in a fitting manner.

3. An energy-saving ventilating structure for architectural design according to claim 1, wherein: the air inlet pipe is characterized in that a movable hinge (4) is fixedly mounted at the top of one side of the air inlet pipe (2), and a closing plate (5) is fixedly connected to one side of the movable hinge (4).

4. An energy-saving ventilating structure for architectural design according to claim 3, wherein: one side of the closing plate (5) is movably connected with an opening at one side of the air inlet pipe (2).

5. An energy-saving ventilating structure for architectural design according to claim 4, wherein: the bottom end of the closing plate (5) is fixedly provided with an inserting rod (6), and one side of the bottom of the air inlet pipe (2) is fixedly provided with an inserting groove plate (7).

6. An energy-saving ventilating structure for architectural design according to claim 5, wherein: the outer surface of the side part of the insertion rod (6) is movably inserted into the inner cavity of the notch formed in one side of the insertion groove plate (7).

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