Continuous integrated air circulation and purification device for hospital and chemical environment
Technical Field
The invention relates to the field of air circulation purification devices, in particular to an absorption and desorption continuous integrated air circulation purification device for hospital and chemical environment.
Background
Hospitals, chemical industries and other environments often require clean and constant-temperature indoor spaces, which have high requirements for air.
In the prior art, ventilation equipment often only introduces the outside air into the room and sets up a coarse and shallow filter screen at the import department, indoor foul smell is directly arranged outside, the filter screen constantly collects up the dust in the use, need the change or the washing of higher frequency, it is very troublesome, and in winter, indoor heat has directly been discharged via foul smell, the new-in outside air is the temperature lower again, greatly increased the load of air conditioner, in summer, indoor low temperature foul smell is discharged, the new-in outside air temperature is higher, also can increase the load of air conditioner.
Disclosure of Invention
The invention aims to provide an absorption and desorption continuous integrated air circulation purification device for hospitals and chemical environments, and aims to solve the problems in the prior art.
In order to achieve the purpose, the invention provides the following technical scheme:
the utility model provides a hospital, chemical industry environment is with inhaling air cycle purifier who separates continuous integral type, including the blast pipe, the intake pipe, first filter screen, the second filter screen, first fan and second fan and return circuit of taking a breath, the return circuit of taking a breath is connected respectively to respective one end of first fan and second fan, the return circuit of taking a breath is connected to the interior space of application scenario, the one end that first fan and second fan deviate from the return circuit of taking a breath separately is gathered and is connected to on the blast pipe, first fan, set up the check valve that the flow direction is towards the blast pipe between second fan and the blast pipe respectively, the one end that first fan and second fan deviate from the return circuit of taking a breath separately still gathers and is connected to in the intake pipe, first fan, set up the check valve that the flow direction is for.
When air enters a room, the air is particularly required to be treated for dust prevention in hospitals and chemical engineering environments, the dust washing device realizes the washing function of dust on the filter screen through the air inlet pipe and the air outlet pipe in a cross form, and the two groups of ventilators and the filter screen, and the realization principle is as follows: when the second fan blows air towards the second filter screen, the check valve between the second filter screen and the air inlet pipe is in a closed state due to the fact that the directions are opposite, air inlet of the air inlet pipe enters from the first filter screen, then the air inlet penetrates through the first filter screen to reach the first fan, at the moment, the first fan is not started or blows air towards the indoor, the filtered air reaches the indoor space through the first fan, and after the indoor space is used, the air inlet reaches the second fan, then the air is blown out from the second filter screen and is discharged to the outside through the exhaust pipe; in the next period, the operation logics of the first fan and the second fan are reversed, namely the first fan is started to blow air towards the first filter screen and the second fan is closed.
Further, the first fan and the second fan are axial flow fans with adjustable flow directions. The axial flow fan with the adjustable flow direction is used for improving the air exchange efficiency, because if the first fan blows air towards the first filter screen to exhaust air outwards, the second fan is in a stop state, and a flow path where the second fan is located only serves as a passive air inlet pipeline, the air inlet resistance of the axial flow fan is large, after the air in the indoor space is pumped away by the first fan, more air outside is sucked from a door gap and a window gap to make up for air loss, and the air entering the indoor space from the gap is not filtered, which is not beneficial to indoor cleanness and sanitation, and after the first fan and the second fan are both the axial flow fans with adjustable directions, an exhaust fan serving as external air blowing and a blower serving as internal air blowing form complete circulation in the indoor space, and the air entering the indoor space is filtered.
Further, the return circuit of taking a breath includes the fresh air pipe, turbid tuber pipe, the water tank, go out tuber pipe and humidity controller, a fresh air pipe is connected respectively to the one end that first fan and second fan are connected the return circuit of taking a breath and the tip is soaked in the water tank, still stretch out turbid tuber pipe with the branch road form on the fresh air pipe, the end-to-end connection indoor space of turbid tuber pipe, set up the check valve that deviates from the indoor space on the turbid tuber pipe, set up the check valve towards the water tank on the fresh air pipe between turbid tuber pipe branch road node and the water tank, it is filled with water and keeps somewhere out the air zone at the top in the water tank, the water tank top surface sets up out the tuber pipe outwards, the end-.
Fresh air pipe, turbid tuber pipe, the water tank, go out tuber pipe and humidity controller's structure and realize humidity control's function, because the check valve direction on the turbid tuber pipe is from indoor toward first fan or second fan, so blow to indoor wind from first fan and second fan and only can follow the fresh air pipe and go and by the drum in the water tank, float and collect at the water tank top with the bubble form in the water tank, arrange to the indoor space via the play tuber pipe, because gas floats from the aquatic, so can bring more moisture, make the humidity of water tank to humidity controller section air very big, humidity controller is according to setting for, the humidity that will flow out gas reduces to certain numerical value can, humidity controller only need carry out humidity and reduce and need not carry out the humidity and increase, so humidity controller's control part can the great degree simplified.
When the second fan blows air to the second filter screen as an exhaust fan, the second fan sucks air through a branch turbid air pipe connected to an inlet pipeline of the second fan, and the first fan supplies air to the room as an air feeder.
Further, the exhaust pipe comprises a section of heat exchange pipe, an exhaust port is formed in the tail end of the exhaust pipe, the heat exchange pipe is immersed in the water body of the water tank, a first pressure regulating valve is arranged on the exhaust pipe, and the first pressure regulating valve is located between the heat exchange pipe and the exhaust port.
The heat exchange tube is used for recovering heat of indoor air, the second fan exhausts air outwards, the air outlet of the second fan passes through the second filter screen and then reaches the head of the exhaust tube, the second fan bends to the heat exchange tube, the heat exchange tube is immersed in the water tank, heat of foul air exhausted from the indoor space is transferred to water in the water tank through the heat exchange tube, and the water heats fresh air entering the indoor space, so that the temperature of the foul air and the temperature of the fresh air are approximately equal, for example, in winter, when outdoor cold air passes through the water tank, the water in the water tank is cooled, and the exhausted foul air heats the water in the water tank through the heat exchange tube. The existence of first air-vent valve makes the heat transfer effect better, adjust a first air-vent valve aperture for a short time, will have the pressure-out from the second fan on the exhaust route of second air-vent valve to first air-vent valve so, pressure on this section of pipeline is compared and will be highly more in external atmosphere, this section of pipeline has included the heat exchange tube, this section of pipeline pressure-out is approximately equal to the pressure drop of first air-vent valve with the difference of atmospheric pressure, the gas in this section of pipeline is compressed, thereby the temperature risees, the heat exchange tube can go with higher temperature and carry out the heat transfer with the water in the water tank, heat in the foul smell is retrieved more fully.
Further, still be equipped with draught fan and second air-vent valve on the blast pipe, the draught fan is located between heat exchange tube and the first air-vent valve, and the second air-vent valve is located one side that the heat exchange tube deviates from the draught fan.
The heat to indoor air needs to be recovered during winter, and the indoor cold quantity needs to be recovered often during summer, namely: the low temperature of the foul gas discharged from the indoor is used for cooling the external high-temperature air which is going to enter the indoor, when the opening degree of the first pressure regulating valve is regulated, high pressure can be caused in the heat exchange pipe, so that the logic of the temperature of the compressed air can not be reversely utilized, the logic needs to be realized through the induced draft fan and the second pressure regulating valve additionally, the principle that the cold energy recovery is realized through the induced draft fan and the second pressure regulating valve is that the branch where the second fan is located is used as an exhaust pipeline, the second fan is closed, the opening degree of the second pressure regulating valve is regulated, the induced draft fan is opened, the first pressure regulating valve is fully opened, thus, a low-pressure area is formed in the pipeline between the induced draft fan and the second pressure regulating valve, the gas is forced to expand on the pipeline at the section, the temperature is reduced, the heat exchange is carried out with the.
As optimization, the ventilation loop further comprises an atomizer which is arranged on the inner wall of the water tank and is immersed in the water body. The atomizer breaks the water in the water tank into fog for the humidity of the air between the top of the water tank and the humidity controller is larger, and a large amount of associated negative oxygen ions can further purify the air after entering the indoor space, so that the environment is improved.
Furthermore, a water replenishing pipe and a water replenishing valve are also arranged on the side wall of the water tank.
The water in the water tank can be continuously reduced in the using process and needs to be supplemented, and the water supplementing valve realizes automatic water supplementing at a specific water level through a lever principle.
As optimization, the first filter screen and the second filter screen are installed in a butt-clamping mode, and butt-clamping flanges on two sides of the first filter screen and the second filter screen are provided with flexible end portions. The two filter screens can be continuously washed by airflow flowing reversely in the using process, but dust and sundries which are difficult to wash can be accumulated after long-time use, and the filter screens need to be replaced, and the replacing period is much longer than that of the filter screens without a back washing structure.
And optimally, differential pressure sensors are respectively arranged on two sides of the first filter screen and the second filter screen, the differential pressure sensor of the first filter screen and the operation of the first fan are in interlocking control, the differential pressure sensor of the second filter screen and the operation of the second fan are in interlocking control, and the first fan and the second fan are in interlocking control. Along with the accumulation of dust on the first filter screen, the pressure differential of its both sides is constantly increasing, can set up certain threshold value for after exceeding certain degree, get into the backwash cycle of this filter screen, for example: when the differential pressure sensor of the first filter screen recognizes that the differential pressure exceeds a certain degree, the first fan is controlled to enter a blowing and exhausting state, and the second fan is switched to enter a draught and air supply state while the first fan enters blowing and exhausting. The control logic of the differential pressure sensor of the second screen is the same.
Compared with the prior art, the invention has the beneficial effects that: according to the invention, the two air inlet branches and the two air outlet branches are freely switched, the external air alternately flows on the filter screens through a section of crossed parallel pipeline in front of the first filter screen and the second filter screen and the fan with adjustable air supply direction behind the first filter screen and the second filter screen, one filter screen is used for air inlet filtration, the other filter screen is used for air outlet and is washed away by the discharged air to remove the dust filtered by the filter screen in the previous period, and continuous adsorption and release are realized; on the gas circuit behind the filter screen, the fresh air is humidified by the water tank and is controlled to have certain humidity through the humidity controller, and the foul air discharged from the indoor space is recovered and stored in the water tank by heat or cold on the exhaust pipe and then is transmitted to the fresh air to enter the indoor space, so that the energy is recycled.
Drawings
In order that the present invention may be more readily and clearly understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings.
FIG. 1 is a schematic diagram of the basic functional flow of the present invention;
FIG. 2 is a schematic view of the screen flushing principle of the present invention;
FIG. 3 is a schematic view of the complete process of the present invention;
FIG. 4 is a schematic view of a flow path of the present invention;
fig. 5 is a schematic diagram of a heat and cold recovery structure of the present invention.
In the figure: 1-exhaust pipe, 11-heat exchange pipe, 19-exhaust port, 2-air inlet pipe, 31-first filter screen, 32-second filter screen, 41-first fan, 42-second fan, 5-ventilation loop, 51-fresh air pipe, 52-turbid air pipe, 53-water tank, 54-air outlet pipe, 55-humidity controller, 56-atomizer, 61-first pressure regulating valve, 62-induced draft fan and 63-second pressure regulating valve.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
As shown in figure 1, the continuous integrated air circulation and purification device for hospital and chemical environment comprises an exhaust pipe 1, an air inlet pipe 2 and a first filter screen 31, second filter screen 32, first fan 41 and second fan 42 and ventilation return circuit 5, ventilation return circuit 5 is connected respectively to first fan 41 and the respective one end of second fan 42, ventilation return circuit 5 is connected to the interior space of application, the one end that first fan 41 and second fan 42 deviate from ventilation return circuit 5 respectively gathers and is connected to blast pipe 1, first fan 41, set up the check valve that the flow direction is towards blast pipe 1 between second fan 42 and the blast pipe 1 respectively, first fan 41 and second fan 42 deviate from ventilation return circuit 5 respectively one end still gathers and is connected to intake pipe 2 on, set up the check valve that the flow direction is for deviating from intake pipe 2 between first fan 41, second fan 42 and the intake pipe 2 respectively.
When air enters a room, the air is particularly required to be treated for dust prevention in hospitals and chemical engineering environments, the dust washing device realizes the washing function of dust on the filter screen through the air inlet pipe 2 and the air outlet pipe 1 in a cross form, and two groups of ventilators and the filter screen, and the realization principle is as follows: as shown in fig. 2, when the second fan 42 blows air toward the second screen 32, the check valve between the second screen 32 and the intake pipe 2 is turned off due to the opposite direction, the intake air of the intake pipe 2 enters from the first screen 31 and then passes through the first screen 31 to reach the first fan 41, at this time, the first fan 41 is not activated or blows air toward the indoor, the filtered air reaches the indoor space via the first fan 41, reaches the air inlet of the second fan 42 after the indoor space is used, and then is blown out from the second screen 32 and discharged to the outdoor from the exhaust pipe 1; in the next period, the operation logics of the first fan 41 and the second fan 42 are reversed, that is, the first fan 41 is started to blow air towards the first filter screen 31 and the second fan 42 is turned off.
The first fan 41 and the second fan 42 are axial fans whose flow directions are adjustable. The axial flow fan with adjustable flow direction is used for improving the air exchange efficiency, because if the first fan 41 blows air towards the first filter screen 31 to exhaust air outwards, the second fan 42 is in a stop state and the flow path of the second fan 42 is just used as a passive air inlet pipeline, the air inlet resistance is larger, after the air in the indoor space is pumped away by the first fan 41, more air is sucked into the outside from the door gap and the window gap to make up for the air loss, and the air entering the indoor space from the gap is not filtered, which is not beneficial to indoor cleanness and sanitation, and after the first fan 41 and the second fan 42 are both the axial flow fans with adjustable directions, one is used as an exhaust fan for blowing air outwards, one is used as a blower for blowing air inwards, a complete circulation is formed in the indoor space, and the air entering the indoor space is filtered.
As shown in fig. 3, the ventilation circuit 5 includes a fresh air pipe 51, a dirty air pipe 52, a water tank 53, an air outlet pipe 54 and a humidity controller 55, one end of the first fan 41 and the second fan 42 connected to the ventilation circuit 5 is respectively connected to one fresh air pipe 51 and the end portion thereof is immersed in the water tank 53, the fresh air pipe 51 further extends out of the dirty air pipe 52 in a branch form, the end of the dirty air pipe 52 is connected to an indoor space, a check valve departing from the indoor space is disposed on the dirty air pipe 52, a check valve facing the water tank 53 is disposed between a branch node of the dirty air pipe 52 on the fresh air pipe 51 and the water tank 53, the water tank 53 is filled with water and has an air region left at the top, the top surface of the water tank 53 is outwardly provided with the air outlet pipe 54, the end of the air outlet pipe 54.
The fresh air pipe 51, the dirty air pipe 52, the water tank 53, the air outlet pipe 54 and the humidity controller 55 are structured to realize the function of humidity adjustment, because the check valve on the dirty air duct 52 is directed from the chamber to either the first fan 41 or the second fan 42, the wind blown into the room from the first and second fans 41 and 42 is blown into the water tank 53 only from the fresh air duct 51, floating in the form of bubbles in the water tank 53 and collected at the top of the water tank 53, and discharged to the indoor space through the air outlet pipe 54, since the air is floated from the water, therefore, a large amount of moisture is brought up, so that the humidity of the air on the section from the water tank 53 to the humidity controller 55 is large, the humidity controller 55 can reduce the humidity of the outflow gas to a certain value according to the setting, and the humidity controller 55 only needs to reduce the humidity without increasing the humidity, so that the control part of the humidity controller 55 can be simplified to a large extent.
As shown in fig. 4, when the second fan 42 is used as an exhaust fan to blow air to the second filter 32, the intake air is taken in through a bypass turbid air duct 52 connected to an inlet pipe thereof, and the first fan 41 is used as a blower to blow air indoors.
As shown in fig. 3, the exhaust pipe 1 includes a section of heat exchange pipe 11, the end of the exhaust pipe 1 is an exhaust port 19, the heat exchange pipe 11 is immersed in the water body of the water tank 53, a first pressure regulating valve 61 is arranged on the exhaust pipe 1, and the first pressure regulating valve 61 is located between the heat exchange pipe 11 and the exhaust port 19.
The heat exchange tube 11 is used for recovering heat of indoor air, as shown in fig. 4, the second fan exhausts air, the outlet air of the second fan passes through the second filter screen 32 and then reaches the head of the exhaust pipe 1, and then is bent to the heat exchange tube 11, the heat exchange tube 11 is immersed in the water tank 53, the heat of the foul air exhausted from the indoor space is transferred to the water in the water tank 53 by the heat exchange tube 11, the water heats the fresh air entering the indoor space, so that the temperature of the foul air is approximately equal to that of the fresh air, for example, in winter, when outdoor cold air passes through the water tank 53, the water in the water tank is cooled, and the exhausted foul air heats the water in the water tank 53 through the heat exchange tube 11. The existence of first air-vent valve 61 makes the heat transfer effect better, adjust first air-vent valve 61 aperture to a small extent, then will have the pressure out on the exhaust route from second fan 42 to first air-vent valve 61, the pressure on this section of pipeline is more than comparing external atmosphere, this section of pipeline has included heat exchange tube 11, this section of pipeline is held up the pressure and the difference of atmospheric pressure is equal to about the pressure drop of first air-vent valve 61, the gas in this section of pipeline is compressed, thereby the temperature rises, heat exchange tube 11 can go with the higher temperature and carry out the heat transfer with the water in the water tank 53, the heat in the foul smell is retrieved more fully.
As shown in fig. 3 and 4, the exhaust pipe 1 is further provided with an induced draft fan 62 and a second pressure regulating valve 63, the induced draft fan 62 is located between the heat exchange pipe 11 and the first pressure regulating valve 61, and the second pressure regulating valve 63 is located on the side of the heat exchange pipe 11 away from the induced draft fan 62.
The heat to indoor air needs to be recovered during winter, and the indoor cold quantity needs to be recovered often during summer, namely: the low temperature of the foul air discharged from the room is used to cool the high temperature air outside the room, when the opening of the first pressure regulating valve 61 is adjusted, the logic that high pressure can be generated in the heat exchange tube 11 so as to increase the temperature of the compressed air cannot be reversely utilized, and needs to be additionally realized by the induced draft fan 62 and the second pressure regulating valve 63, the principle that the induced draft fan 62 and the second pressure regulating valve 63 realize cold recovery is that, as shown in fig. 4 and 5, the branch where the second fan 42 is located is used as an exhaust line, the second fan 42 is turned off, the opening degree of the second pressure regulating valve 63 is reduced, the induced draft fan 62 is turned on, the first pressure regulating valve 61 is fully opened, thus, a low pressure area is formed in the pipe between the induced draft fan 62 and the second pressure regulating valve 63, on this section of pipeline, the gas is forced to expand, the temperature is reduced, the heat exchange tube 11 exchanges heat with the water in the water tank 53 at a lower temperature, and the cold energy of the foul air discharged from the indoor space is more fully recovered.
As shown in fig. 3, the ventilation circuit 5 further includes an atomizer 56, and the atomizer 56 is disposed on an inner wall of the water tank 53 and is immersed in the water body. The atomizer 56 breaks the water in the water tank 53 into mist, so that the humidity of the air between the top of the water tank 53 and the humidity controller 55 is higher, and a large amount of accompanying negative oxygen ions can further purify the air after entering the indoor space, thereby improving the environment.
The side wall of the water tank 53 is also provided with a water replenishing pipe and a water replenishing valve.
The water in the water tank 53 can be continuously reduced in the using process and needs to be supplemented, and the water supplementing valve realizes automatic water supplementing at a specific water level through a lever principle.
As shown in fig. 1, the first screen 31 and the second screen 32 are installed in a butt-clamped manner, and the butt-clamped flanges at both sides of the first screen 31 and the second screen 32 are provided with flexible end portions. The two filter screens can be continuously washed by airflow flowing reversely in the using process, but dust and sundries which are difficult to wash can be accumulated after long-time use, and the filter screens need to be replaced, and the replacing period is much longer than that of the filter screens without a back washing structure.
Differential pressure sensors are respectively arranged on two sides of the first filter screen 31 and the second filter screen 32, the differential pressure sensor of the first filter screen 31 and the operation of the first fan 41 are in interlocking control, the differential pressure sensor of the second filter screen 32 and the operation of the second fan 42 are in interlocking control, and the first fan 41 and the second fan 42 are in interlocking control. Along with the accumulation of dust on first filter screen 31, the pressure differential of its both sides is constantly increasing, can set up certain threshold value for after exceeding a certain degree, enter the backwash cycle of this filter screen, for example: when the differential pressure sensor of the first filter screen 31 recognizes that the differential pressure exceeds a certain degree, the first fan 41 is controlled to enter a blowing and exhausting state, and the second fan 42 is switched to enter a blowing and air supplying state while the first fan 41 enters blowing and exhausting. The control logic of the differential pressure sensor of the second screen 32 is the same.
The main operation process of the device is as follows: the external air realizes the alternate flow of the air on the filter screens through a section of crossed parallel pipeline in front of the first filter screen 31 and the second filter screen 32 and the fans with adjustable air supply directions behind the first filter screen 31 and the second filter screen 32, one filter screen is used for air inlet filtration, the other filter screen is used for air exhaust, and the dust filtered by the filter screen in the previous period is washed away by the outflowing air, so that the continuous adsorption and release are realized; on the air path behind the filter screen, the fresh air is humidified by the water tank 53 and controlled to a certain humidity by the humidity controller 55, and the foul air discharged from the indoor space is recovered and stored in the water tank 53 by heat or cold on the exhaust pipe 1 and then transmitted to the fresh air to enter the indoor space.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention 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.