Patent Description:
Existing ventilation-air conditioners generally have an air outlet of an open structure during operation. When a ventilation component works, air output from an air conditioner is stopped by a baffle. However, when the ventilation component is not working, a ventilation outlet cannot be closed by the baffle. If the ventilation component is not working for a long time, dust may enter the interior of the ventilation component through the ventilation outlet from outside, resulting in failures in the ventilation component.

<CIT> discloses an air conditioner indoor unit and an air conditioner with the air conditioner indoor unit. The air conditioner indoor unit comprises a machine shell, a fan assembly, a first driving mechanism, a first opening and closing door, a second driving mechanism and a second opening and closing door. An air inlet, a first air outlet and a second air outlet are formed in the machine shell. Fan assembly arranged in machine shell, the first driving mechanism is connected with the first switch door to drive the first switch door to reciprocate; the first switch door has an open state and a closed state; in an open state, the first driving mechanism drives the first opening and closing door to move outwards relative to the machine shell to a set position to open the first air outlet, in the closed state, the first opening and closing door is matched with the machine shell to close the first air outlet, and the second driving mechanism is connected with the second opening and closing door to drive the second opening and closing door to slide relative to the machine shell to open or close the second air outlet. According to the indoor unit of the air conditioner, the sense of science and technology of products is high, air supply is uniform, and the use comfort of the indoor unit of the air conditioner is greatly improved.

The present invention provides a ventilation and air conditioning system, and aims to reduce failures of a ventilation component due to dust which enters through a ventilation outlet when the ventilation component is not in use.

The present invention provides a ventilation and air conditioning system as defined by claim <NUM>.

Preferably, the automatic air-output device defines a first position and a second position, when the automatic air-output device is located at the first position (when the automatic air-output device closes the ventilation outlet), an outer surface of an outer panel of the automatic air-output device and an outer surface of a housing of the ventilation and air conditioning body are located on a common plane; and when the automatic air-output device is located at the second position (when the automatic air-output device opens the ventilation outlet), the outer panel of the automatic air-output device changes with respect to the outer surface of the housing of the ventilation and air conditioning body according to the operating state of the ventilation component.

Preferably, the ventilation outlet is located on the outer surface of the ventilation and air conditioning body, and the outer panel of the automatic air-output device is slidably arranged at the ventilation outlet.

Preferably, the ventilation outlet is provided with a sliding groove, the automatic air-output device is provided with a sliding block, the sliding block is fitted with the sliding groove, and an inner wall of the ventilation component is provided with a driving mechanism configured to drive the automatic air-output device to slide back and forth.

Preferably, the ventilation outlet is located on the outer surface of the ventilation and air conditioning body, the automatic air-output device is configured as a cylindrical structure, and an axial central line of the automatic air-output device is perpendicular to the outer surface of the ventilation and air conditioning body. An ejecting mechanism ejects the automatic air-output device according to the operating state of the ventilation component, to make an outer surface of an outer panel of the automatic air-output device protrude beyond the outer surface of the ventilation and air conditioning body, or, the ejecting mechanism retracts the automatic air-output device according to the operating state of the ventilation component, to make the outer surface of the outer panel of the automatic air-output device located on the same plane as the outer surface of the ventilation and air conditioning body.

Preferably, an outer peripheral wall of the automatic air-output device is provided with an air output groove, and the automatic air-output device adjusts a size of the air output groove through rotation of the automatic air-output device about an axial central line of the automatic air-output device by means of a driving mechanism.

Preferably, the automatic air-output device is arranged at the ventilation outlet through a driving mechanism. The driving mechanism pushes the outer panel of the automatic air-output device out in a direction away from the outer surface of the ventilation and air conditioning body or retracts the outer panel of the automatic air-output device according to the operating state of the ventilation component, to regulate a direction and volume of air output through the ventilation outlet.

Preferably, at least two groups of driving devices are arranged on an inner surface of the automatic air-output device. Each of the driving devises can be configured to push an end of the automatic air-output device to open the ventilation outlet, and the automatic air-output device is pushed in a parallel manner or an oblique manner.

The present invention provides beneficial effects as follows.

With the automatic air-output device arranged at the ventilation outlet of the ventilation component, the automatic air-output device is associated with power on and power off of the ventilation component. When the ventilation component is powered on, the automatic air-output device is triggered therewith to open the ventilation outlet of the ventilation component, to allow fresh air of the ventilation component to flow indoors. When the ventilation component is powered off, the automatic air-output device is triggered therewith to close the ventilation outlet. As a result, the ventilation outlet can be in a closed state when the ventilation component is not in use, thereby reducing accumulation of dust in the ventilation component caused by that the ventilation component not being used, so as to reduce dust-related failures of the ventilation component and prolong the service life of the ventilation component.

Other features and advantages of the present invention disclosure will be described in the following description, and will be partly obvious from the specification, or may be understood by implementing the present invention.

The objectives and other advantages of the present invention may be implemented and achieved by the written description and the structures indicated particularly in the accompanying drawings.

Implementations of the technical schemes of the present invention will be further described in detail in combination with drawings and embodiments.

The accompanying drawings, which are included to provide a further understanding of the present invention and constitute a part of this specification, serve to illustrate the present invention with the embodiments, but do not limit the present invention which is defined by the appending claims.

Preferred embodiments of the invention will be described in conjunction with the accompanying drawings, and it shall be understood that the preferred embodiments described here are only for describing and explaining the present invention rather than limiting the present invention.

As illustrated in <FIG>, an embodiment of the present disclosure provides a ventilation and air conditioning system. The ventilation and air conditioning system can include a ventilation and air conditioning body, and an automatic air-output device <NUM> arranged at a ventilation outlet <NUM> of the ventilation and air conditioning body. The ventilation and air conditioning body includes a ventilation component <NUM>. The automatic air-output device <NUM> is configured to open or close the ventilation outlet <NUM> according to an operating state of the ventilation component <NUM>. When the automatic air-output device <NUM> closes the ventilation outlet <NUM>, an outer surface of an outer panel of the automatic air-output device <NUM> and an outer surface of a housing of the ventilation and air conditioning body are located on a common plane. When the automatic air-output device <NUM> opens the ventilation outlet <NUM>, the outer panel of the automatic air-output device <NUM> varies with respect to the outer surface of the housing of the ventilation and air conditioning body according to the operating state of the ventilation component <NUM>.

With the automatic air-output device <NUM> arranged at the ventilation outlet <NUM> of the ventilation component <NUM>, the automatic air-output device <NUM> is coupled to a power switch of the ventilation component <NUM>. When the power switch is the ventilation component <NUM> is turned on, the automatic air-output device <NUM> is triggered therewith to open the ventilation outlet of the ventilation component, to allow fresh air of the ventilation component <NUM> to flow indoors. When the power switch of the ventilation component <NUM> is turned off, the automatic air-output device <NUM> is triggered therewith to close the ventilation outlet <NUM>. As a result, the ventilation outlet <NUM> can be in a closed state when the ventilation component <NUM> is not working, thereby reducing accumulation of dust in the ventilation component <NUM> caused by that the ventilation component <NUM> not being used, so as to reduce dust-related failures of the ventilation component <NUM> and prolong the service life of the ventilation component <NUM>.

The outer surface of the housing of the ventilation and air conditioning body is a front surface of the ventilation and air conditioning body, a rear surface of the ventilation and air conditioning body is configured to be mounted indoors. The front surface of the ventilation and air conditioning body may be flat or curved. The outer panel of the automatic air-output device is configured to adapt to a shape of the outer surface of the housing of the ventilation and air conditioning body.

As illustrated in <FIG> and <FIG>, the ventilation outlet <NUM> is located on an outer surface of the ventilation and air conditioning body, and an outer panel of the automatic air-output device <NUM> is slidably arranged at the ventilation outlet <NUM>.

The ventilation outlet <NUM> is provided with a sliding groove <NUM>, and the automatic air-output device <NUM> is provided with a sliding block <NUM>. The sliding block <NUM> is fitted with the sliding groove <NUM>. An inner wall of the ventilation component <NUM> is provided with a driving mechanism configured to drive the automatic air-output device <NUM> to slide back and forth.

The driving mechanism can allow the automatic air-output device to slide at the ventilation outlet, to enable the automatic air-output device to open or close the ventilation outlet during its sliding, and regulate air output volume from the ventilation outlet. In this embodiment, an outer surface of the outer panel of the automatic air-output device and the outer surface of the ventilation and air conditioning body are on a common plane, and the outer panel of the automatic air-output device slides reciprocally on the plane to open or close the ventilation outlet.

Specifically, a side of the automatic air-output device adjacent to an interior of the ventilation component is provided with a toothed plate. The toothed plate <NUM> engages with a third gear, and the third gear is connected to a drive motor through a coupling. When the drive motor drives the third gear to rotate, the third gear and the toothed plate engage with each other, and the toothed plate slides by means of the sliding groove and the sliding block. Thus, the automatic air-output device can open or close the ventilation outlet via the movement of the sliding groove and the sliding block, and regulate the air output volume of the ventilation outlet. Moreover, the ventilation outlet is closed when not in use, thereby lowering the possibility that dust enters the ventilation component through the ventilation outlet and causes damage to the ventilation component when the ventilation component is not in use.

The ventilation outlet <NUM> is perpendicular to a sliding direction of the automatic air-output device. When the automatic air-output device is located at the ventilation outlet and slides, the automatic air-output device can open an opening of the ventilation outlet to output the fresh air from the ventilation component into the indoors. The automatic air-output device has an area larger than a maximum area of the opening of the ventilation outlet.

Specifically, for example, the ventilation outlet is located at an upper half portion of an inner surface of the automatic air-output device. In such a case, when the ventilation outlet needs opening to output air, the automatic air-output device slides downwards; when the ventilation outlet needs closing, the automatic air-output device slides upwards to close the opening of the ventilation outlet.

For example, the ventilation outlet is located at a lower half portion of the inner surface of the automatic air-output device. In such a case, when the ventilation outlet needs opening to output air, the automatic air-output device slides upwards to open the ventilation outlet; when the ventilation outlet needs closing, the automatic air-output device slides downwards to close the ventilation outlet.

As illustrated in <FIG> and <FIG>, the ventilation outlet <NUM> is located on an outer surface of the ventilation and air conditioning body, and the automatic air-output device <NUM> is configured as a cylindrical structure. An axial central line of the automatic air-output device <NUM> is perpendicular to the outer surface of the ventilation and air conditioning body. An ejecting mechanism pushes out the automatic air-output device <NUM> according to an operating state of the ventilation component <NUM>, to make an outer surface of an outer panel of the automatic air-output device <NUM> protrude beyond the outer surface of the ventilation and air conditioning body. Alternatively, the ejecting mechanism retracts the automatic air-output device <NUM> according to the operating state of the ventilation component <NUM>, to make the outer surface of the outer panel of the automatic air-output device <NUM> located on the same plane as the outer surface of the ventilation and air conditioning body. The automatic air-output device <NUM> has an outer peripheral wall provided with an air output groove <NUM>, and the automatic air-output device <NUM> adjusts the size of the air output groove <NUM> through rotation of the automatic air-output device around its own axial central line by means of a driving mechanism.

After the ejecting mechanism pushes out the automatic air-output device at the ventilation outlet, the driving mechanism can further rotate the automatic air-output device to change the size of the air output groove, and hence the air output volume from the ventilation outlet can be regulated. In this embodiment, when the automatic air-output device starts to work, the outer panel thereof protrudes from the ventilation component, such that the outer panel of the automatic air-output device is higher than the outer surface of the ventilation and air conditioning body, and then the automatic air-output device is rotated to achieve the purpose that the automatic air-output device adjusts the air output groove.

Specifically, the automatic air-output device is configured as the cylindrical structure; an outer peripheral wall of an end of the automatic air-output device in the interior of the ventilation component is provided with teeth; the end provided with the teeth is configured to engage with a fourth gear; and the fourth gear is connected to a drive motor. When the air output groove needs to be adjusted, the drive motor drives the fourth gear to rotate, and after rotation, the fourth gear engages with the teeth provided on the outer peripheral wall of the automatic air-output device, such that the size of the air output groove can be adjusted. That is, the air output volume from the ventilation outlet can be regulated by the rotation of the automatic air-output device. Preferably, the ejecting mechanism is a linear drive motor.

As illustrated in <FIG> and <FIG>, the automatic air-output device <NUM> is arranged at the ventilation outlet <NUM> via a driving mechanism, the driving mechanism ejects an outer panel of the automatic air-output device <NUM> away from an outer surface of the ventilation and air conditioning body or retracts the outer panel of the automatic air-output device <NUM> according to an operating state of the ventilation component <NUM>, such that an air output direction and air output volume of the ventilation outlet <NUM> can be regulated. At least two groups of driving devices are provided on an inner surface of the automatic air-output device <NUM>. The driving devices each are configured to push a corresponding end of the automatic air-output device and open the ventilation outlet <NUM>. Pushing the automatic air-output device <NUM> includes pushing the automatic air-output device <NUM> in a parallel manner or an oblique manner.

When the ventilation component <NUM> is turned on, the automatic air-output device is triggered synchronously. The driving mechanism of the automatic air-output device ejects the automatic air-output device, and an angle of ejecting the automatic air-output device is correspondingly adjusted along with the operating state of the ventilation component. In this embodiment, after starting to work, the outer panel of the automatic air-output device <NUM> is in parallel with and higher than the outer surface of the ventilation and air conditioning body, or the outer panel of the automatic air-output device is adjusted to be inclined with respect to the outer surface of the ventilation and air conditioning body, according to the operating state of the ventilation component, so as to achieve the purpose of air direction adjustment.

Specifically, a drive motor is arranged inside the ventilation component, an end of the drive motor adjacent to the ventilation outlet is provided with a telescoping rod, and an end of the telescoping rod away from the drive motor is connected to the inner surface of the automatic air-output device. Preferably, the drive motor is a linear drive motor. The linear drive motor enables the telescoping rod to stretch or retract, and an angle between the automatic air-output device and a section of the ventilation outlet can be adjusted. At least two drive motors are provided. When the two drive motors work together, the automatic air-output device can be pushed out in parallel with a flow direction of the fresh air from the ventilation outlet. When one of the two drive motors works and the other one does not work, an air outlet is formed at an end of the automatic air-output device where the drive motor is working, such that a purpose of outputting the fresh air obliquely is realized, and various air direction adjustments to the air outlet of the ventilation outlet can be achieved.

As illustrated in <FIG>, the ventilation and air conditioning body includes a ventilation component <NUM> and a heat exchanging component <NUM>. The ventilation component <NUM> and the heat exchanging component <NUM> are arranged in a common housing <NUM> and separated by a partition board <NUM>. A ventilation inlet <NUM> of the ventilation component <NUM> is in communication with a purification chamber <NUM> through an air inlet duct <NUM>. An end of the purification chamber <NUM> away from the air inlet duct <NUM> is provided with a ventilation outlet <NUM>. The purification chamber <NUM> is provided with a filter screen <NUM> therein. A first blower <NUM> is provided between the filter screen <NUM> and the ventilation outlet <NUM>, and the first blower <NUM> is arranged adjacent to the ventilation outlet <NUM>. The ventilation component <NUM> and the heat exchanging component <NUM> are arranged in the same housing <NUM> and separated by the partition board <NUM>. A heat exchanging unit <NUM> is provided between a heat exchanging inlet <NUM> and a heat exchanging outlet <NUM> of the heat exchanging component <NUM>. The heat exchanging unit <NUM> has a U-shaped structure. An open end of the U-shaped structure faces downward and is provided with a second blower <NUM>, and the second blower <NUM> is arranged adjacent to the heat exchanging outlet <NUM>. The heat exchanging outlet <NUM> is configured for the air inlet duct <NUM> to pass through, run through the housing <NUM>, and extend to an exterior of a side of the housing <NUM> away from the ventilation component <NUM>.

The heat exchanging inlet <NUM> of the heat exchanging component <NUM> is configured to guide indoor air to the heat exchanging unit <NUM>. The air that has undergone heat exchange by the heat exchanging unit <NUM> is discharged from the heat exchanging outlet <NUM> and the second blower arranged above the heat exchanging outlet <NUM>.

Furthermore, the air inlet duct <NUM> of the ventilation component <NUM> passes through the heat exchanging outlet <NUM>, and air flowing through the air inlet duct <NUM> can experience pre-heat exchange by the heat exchanging outlet <NUM>, such that the air entering the purification chamber <NUM> from the air inlet duct <NUM> has gone through pre-heat exchange, further reducing a difference between a temperature of air purified by the ventilation component <NUM> and an indoor temperature, and significantly improving comfort for indoor users.

A side of the heat exchanging component <NUM> away from the ventilation component <NUM> is provided with a control chamber, the control chamber is connected to a display screen <NUM> via a wire, and the display screen is embedded in an outer surface of the housing <NUM>. The heat exchanging inlet <NUM> is provided with an air inlet screen, and the air inlet screen is detachably arranged at an upper top surface of the housing <NUM>.

The air inlet screen can filter air entering the heat exchanging component <NUM> and uniformly guide outdoor air into the heat exchanging component <NUM> for heat exchange. The control chamber is configured to be connected to a power supply, to drive the heat exchanging unit <NUM> and the second blower <NUM> of the heat exchanging component <NUM>, and to drive a first motor of the ventilation component <NUM> and the automatic air-output device <NUM>. The display screen <NUM> is configured to display an operating stare of the heat exchanging component <NUM> or the ventilation component <NUM>.

As illustrated in <FIG>, an outer surface of the housing <NUM> is provided with a mount, and the mount is arranged at a side away from the display screen.

The mount can enable the housing to be smoothly hung indoors, and the heat exchanging component <NUM> or the ventilation component <NUM> can be used to exchange heat or generate fresh air indoors.

The heat exchanging outlet is provided with an air-conditioner wind shield, and the air-conditioner wind shield can be started together with the heat exchanging component, to open or close the heat exchanging outlet.

As illustrated in <FIG>, the ventilation component can be provided with a filter replacement device therein, and the filter replacement device is connected to a controller. The first blower is provided with a rotation-speed acquiring device, and the rotation-speed acquiring device is connected to the controller via a wire.

The controller monitors an operating state of the ventilation component by acquiring a rotation speed of the first blower. When the rotation speed of the first blower exceeds a preset value, the controller starts the filter replacement device, such that the filter replacement device can replace the filter screen automatically, which reduces manual regular replacement of filters, and significantly raises efficiency of indoor air purification of the ventilation component. In addition, since the filter screen is replaced in time, damage to the ventilation component caused by dirt from a waste filter screen can be reduced, significantly prolonging the service life of the ventilation component.

As illustrated in <FIG>, the filter replacement device includes a fourth rotating shaft <NUM>, a pushing mechanism, and a switching mechanism. The fourth rotating shaft <NUM> runs through a replacement casing <NUM>. The replacement casing <NUM> is configured to fix the filter replacement device in the ventilation component. A first end of the fourth rotating shaft <NUM> located outside the replacement casing <NUM> is connected to a motor, a second end of the fourth rotating shaft <NUM> is connected to the switching mechanism. A side of the fourth rotating shaft <NUM> adjacent to an inner wall of the replacement casing <NUM> is sequentially provided with a second gear <NUM> and a cam <NUM> which are spaced apart from each other. A first gear <NUM> is provided below and engages with the second gear <NUM>. A side of the first gear <NUM> adjacent to the replacement casing <NUM> is provided with a third rotating shaft <NUM>. The third rotating shaft <NUM> runs through the inner wall of the replacement casing <NUM> and extends out of an outer wall of the replacement casing <NUM>. An end of the third rotating shaft <NUM> extending out of the outer wall of the replacement casing <NUM> is connected to an indicator board <NUM>. The outer wall of the replacement casing <NUM> is provided with a display disc <NUM>, and a plurality of filter indication marks are uniformly distributed on the display disc <NUM>. A third fixed plate <NUM> is provided between the cam <NUM> and the switching mechanism. The fourth rotating shaft <NUM> is rotatably arranged to the replacement casing <NUM> and the third fixed plate <NUM>. The third rotating shaft <NUM> is rotatably arranged to the replacement casing <NUM>. The switching mechanism includes a first rotating shaft <NUM>, a hemispheroid <NUM>, and a switch lever <NUM>. The first rotating shaft <NUM> has a first end rotatably arranged on a bearing seat <NUM>. An end of the bearing seat <NUM> away from the first rotating shaft <NUM> is fixed to an inner surface of the replacement casing <NUM>. The first rotating shaft <NUM> has a second end running through the hemispheroid <NUM> and connected to a first turntable <NUM>. The first turntable <NUM> has an upper surface provided with a plurality of storage boxes <NUM> which are spaced apart from each other. Each storage box <NUM> has an inner bottom provided with a through hole <NUM>, and the through hole <NUM> runs through the storage box <NUM> and the first turntable <NUM>. An axial central line of the hemispheroid <NUM> coincides with an axial central line of the first rotating shaft <NUM>. A first surface of the hemispheroid <NUM> adjacent to the first turntable <NUM> is a spherical concave surface, and a second surface of the hemispheroid <NUM> adjacent to the bearing seat <NUM> is a spherical convex surface. An edge of the hemispheroid <NUM> is provided with a plurality of switch holes <NUM> which are spaced apart from each other, and an arc notch <NUM> is arranged between every two the switch holes <NUM>. An end portion of the fourth rotating shaft <NUM> is connected to a connecting disc <NUM>. A side of the connecting disc <NUM> away from the third fixed plate <NUM> is connected to a first connecting rod <NUM>. An end of the first connecting rod <NUM> away from the connecting disc <NUM> is provided with a protruding block <NUM>. A side of the protruding block <NUM> adjacent to the first connecting rod <NUM> is provided with a switch lever <NUM>. The switch lever <NUM> is configured to cooperate with the switch holes <NUM> to drive the hemispheroid <NUM> to rotate. A side of the first connecting rod <NUM> away from the protruding block <NUM> is provided with an arc baffle <NUM> protruding towards a direction of the hemispheroid <NUM>. The arc baffle <NUM> and the arc notch <NUM> cooperate with each other, and a diameter of the arc baffle <NUM> is less than a diameter of the arc notch <NUM>. A surface of the replacement casing <NUM> adjacent to the storage box <NUM> is provided with a via hole <NUM>. The via hole <NUM> is configured in such a way that the pushing mechanism can push the filter screen <NUM> out of the storage box <NUM> to the purification chamber <NUM> through the via hole <NUM>.

A third connecting plate <NUM> is provided below the cam <NUM>, a side of the third connecting plate <NUM> is provided with a six rotating shaft <NUM>, and the six rotating shaft <NUM> is rotatably arranged to the second fixed plate <NUM>. An end of the second fixed plate <NUM> is fixed to the inner wall of the replacement casing <NUM>. An end of the six rotating shaft <NUM> away from the third connecting plate <NUM> is connected to a second connecting plate <NUM>, and the second connecting plate <NUM> is located at a side of the second fixed plate <NUM> away from the third connecting plate <NUM>. A side of the second connecting plate <NUM> away from the six rotating shaft <NUM> is fixedly provided with a fifth rotating shaft <NUM>, and another end of the fifth rotating shaft <NUM> is fixedly connected to a first connecting plate <NUM>. A side of the first connecting plate <NUM> away from the fifth rotating shaft <NUM> is fixedly connected to a second rotating shaft <NUM>. The second rotating shaft <NUM> runs through and is rotatably arranged to a first fixed plate <NUM>. A first end of the first fixed plate <NUM> is fixed to the inner wall of the replacement casing <NUM>. An end of the second rotating shaft <NUM> away from the first connecting plate <NUM> is fixedly connected to a fourth connecting rod <NUM>, and another end of the fourth connecting rod <NUM> is rotatably connected to a U-shaped hole of a U-shaped bracket <NUM>. A surface of the U-shaped bracket <NUM> away from the U-shaped hole is provided with a third connecting rod <NUM>, and another end of the third connecting rod <NUM> is symmetrically provided with another U-shaped bracket <NUM>. A second connecting rod <NUM> is rotatably connected in a U-shaped hole of the another U-shaped bracket <NUM>. A first end of the second connecting rod <NUM> is articulated with a first limiting block <NUM>. A side of the first limiting block <NUM> away from the second connecting rod <NUM> is fixed to the inner wall of the replacement casing <NUM>. A second end of the second connecting rod <NUM> is clamped by two clamping plates <NUM> and fixed together therewith. An upper side of one clamping plate <NUM> adjacent to a bottom surface of the first turntable <NUM> is provided with supporting rods <NUM> spaced apart from each other. A bearing plate <NUM> is provided on ends of the supporting rods <NUM> away from the clamping plate <NUM>, and the bearing plate <NUM> is configured to push up the filter screen <NUM>.

When the filter screen in the purification chamber needs to be replaced, the controller sends an instruction to the motor. When the motor rotates, the fourth rotating shaft is driven to rotate, and the cam, the second gear, and the switching mechanism are driven to rotate together as the fourth rotating shaft rotates.

After the cam rotates, a protruding end of the cam comes in contact with the third connecting plate, such that the third connecting plate <NUM> can be pressed downwards, and the end of the third connecting plate moves downwards to drive the six rotating shaft to rotate. When the six rotating shaft rotates, the second connecting plate and the fifth rotating shaft are driven to rotate together. In turn, the rotation of the fifth rotating shaft drives the first connecting plate to rotate. The first connecting plate drives the second rotating shaft to rotate. The rotation of the second rotating shaft drives the fourth connecting rod to move up and down. The upward and downward movement of the fourth connecting rod is transmitted through the U-shaped bracket and the third connecting rod, so that the second connecting rod performs lever movement under the action of the movement of the U-shaped bracket or the articulation of the first limiting block, and an end of the second connecting rod away from the first limiting block is pushed upwards. Thus, the pushing mechanism pushes up the filter screen on the first turntable into the purification chamber.

The switching mechanism works by the rotation of the fourth rotating shaft. Specifically, the fourth rotating shaft rotates to drive the connecting disc to rotate, and the first connecting rod and the arc baffle which are connected to the connecting disc are also brought into rotation, which further enables the protruding block and the switch lever to rotate together. The protruding block and the switch lever conduct circular motion about an axial central line of the fourth rotating shaft, and drive the switch holes arranged at intervals in the hemispheroid to switch, such that the hemispheroid can rotate via the first rotating shaft and the bearing seat. When the first rotating shaft rotates, the first turntable is driven to rotate, such that the storage boxes on the upper surface of the first turntable rotate. As the storage boxes rotate, the storage box with a new filter screen is driven to rotate to the via hole in the replacement casing. The new filter screen is pushed out of the storage box and the replacement casing by the pushing mechanism, and then reaches the purification chamber to be used. The old filter screen falls into a corresponding storage box when the pushing mechanism moves downwards. Thus, the replacement of the filter screen is realized.

Furthermore, in order to observe the filter screens in the storage boxes clearly, the second gear during rotation engages with the first gear. When the first gear rotates, the third rotating shaft is driven to rotate. The rotation of the third rotating shaft drives the indicator board to rotate. The display disc is provided with at least four indication marks, the indication marks are in one-to-one correspondence with the storage boxes, and the indication marks are numbers which are ordered. An initial state of the indicator board is numbered as <NUM>, and a finishing state thereof is numbered as <NUM>. When the fourth rotating shaft rotates, the filter screen is replaced once by cooperation of the switching mechanism and the pushing mechanism. The indicator board rotates once and correspondingly rotates to an indication mark of the filter screen in use, which makes it convenient for a user to check a using state of the filter screen at any time during operation, and also makes it easy to store new filter screens in the storage boxes when all of the filter screens in the storage boxes are used.

Claim 1:
A ventilation and air conditioning system, characterized in comprising:
a ventilation and air conditioning body comprising a ventilation component (<NUM>) and a heat exchanging component (<NUM>) arranged in a common housing (<NUM>) and separated by a partition board (<NUM>), wherein the ventilation component (<NUM>) has a ventilation outlet (<NUM>), and the heat exchanging component (<NUM>) has a heat exchanging inlet (<NUM>) and a heat exchanging outlet (<NUM>),
wherein the ventilation and air conditioning system comprises an automatic air-output device (<NUM>) arranged at the ventilation outlet (<NUM>), the automatic air-output device (<NUM>) being configured to open or close the ventilation outlet (<NUM>) according to an operating state of the ventilation component (<NUM>);
a ventilation inlet (<NUM>) of the ventilation component (<NUM>) is in communication with a purification chamber (<NUM>) through an air inlet duct (<NUM>), and an end of the purification chamber (<NUM>) away from the air inlet duct (<NUM>) is provided with the ventilation outlet (<NUM>);
the purification chamber (<NUM>) is provided with a filter screen (<NUM>) therein, a first blower (<NUM>) is provided between the filter screen (<NUM>) and the ventilation outlet (<NUM>), and the first blower (<NUM>) is arranged adjacent to the ventilation outlet (<NUM>);
a heat exchanging unit (<NUM>) is provided between the heat exchanging inlet (<NUM>) and the heat exchanging outlet (<NUM>) of the heat exchanging component (<NUM>), the heat exchanging unit has a U-shaped structure, an open end of the U-shaped structure faces downward and is provided with a second blower (<NUM>) that is arranged adjacent to the heat exchanging outlet (<NUM>); and
the heat exchanging outlet (<NUM>) is configured for the air inlet duct (<NUM>) to pass through and extend through the housing, and extend to an exterior of a side of the housing away from the ventilation component (<NUM>).