CN113110652B - Automatic temperature and humidity monitoring and control device and method for artificial climate room - Google Patents

Abstract

The invention relates to the technical field of climatic rooms, in particular to a temperature and humidity automatic monitoring and controlling device and method for an artificial climatic room. The device comprises a substrate, wherein a wall body and a base station are arranged on the substrate, a first turbofan, a second turbofan and a temperature and humidity sensor are arranged on the side wall of the wall body, and a wet curtain and a negative pressure fan are respectively arranged on two sides of the wall body and used for increasing the humidity in a climate room; a converging channel is formed between the wall body and the base station at intervals and used for forming converging water flow, the first water pump impeller is arranged in the middle of the converging channel, and the second water pump impeller is arranged in the middle of the converging channel; the controller and the driving mechanism are arranged in the base station and used for driving the first water pump impeller and the second water pump impeller to rotate so as to drive water flow to flow; the controller signal input end is electrically connected with the temperature and humidity sensor, the controller output end is electrically connected with the first turbofan, the controller output end is electrically connected with the second turbofan, and the controller output end is electrically connected with the negative pressure air fan.

Description

Automatic temperature and humidity monitoring and control device and method for artificial climate room

Technical Field

The invention relates to the technical field of climatic rooms, in particular to a temperature and humidity automatic monitoring and controlling device and method for an artificial climatic room.

Background

The artificial climate house is a high-precision cold and hot constant temperature device with humidifying function, provides an ideal artificial climate experimental environment for users, can be used for the culture of germination, seedling, tissue and microorganism of plants, the breeding of insects and small animals, the BOD determination of water body analysis and artificial climate tests of other purposes, and is an ideal experimental device for production and scientific research departments of biological genetic engineering, medicine, agriculture, forestry, environmental science, livestock raising, aquatic products and the like.

Traditional artificial climate room only possesses heat dissipation and ventilation, to temperature, humidity regulation and control is not in place, the independent regulation and control to temperature or humidity will certainly influence the growth adaptability of plant, bacterial, microorganism to sudden change environment in the climate room by a wide margin, influence periodic test result contrast, because lie in the regulation and control of humidity, current conventional way is to carry out the humidification to the air through spraying or spraying when climate room humidity is not enough, lead to indoor humiture drastic change, the drop change of humiture can not accepted to many plant seedlings growing or bacterial, microorganism etc. leads to physiological function to descend, some is serious even leads to rotten root, internal environment stability is not good.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an automatic temperature and humidity monitoring and controlling device and method for a phytotron to solve the problems.

The technical scheme of the invention is as follows: an automatic temperature and humidity monitoring and control device for a phytotron comprises:

the device comprises a base, wherein a wall body and a base station are arranged on the base, a first turbofan, a second turbofan and a temperature and humidity sensor are arranged on the side wall of the wall body, and a wet curtain and a negative pressure fan are respectively arranged on two sides of the wall body and used for increasing the humidity in a climate room;

the water pump comprises a converging channel, a first water pump impeller and a second water pump impeller, wherein the converging channel is formed between the wall body and the base platform at intervals and used for forming converging water flow;

the controller is used for collecting information and linking signals with climate room temperature and humidity control to provide multiple mode selection; the driving mechanism is arranged in the base station, is in gear transmission with the first water pump impeller and the second water pump impeller respectively, and is used for driving the first water pump impeller and the second water pump impeller to rotate so as to drive water flow to flow;

the controller signal input end is electrically connected with the temperature and humidity sensor, the controller output end is electrically connected with the first turbofan, the controller output end is electrically connected with the second turbofan, and the controller output end is electrically connected with the negative pressure air fan.

As a further improvement of the technical scheme of the invention, the top of the wall body is a roof provided with a vent, suspension beams are connected between the wall bodies, and a middle beam is connected between the suspension beams and the roof and used for supporting the roof.

As a further improvement of the technical scheme of the invention, the driving mechanism comprises a first gear, a second gear, a third gear, a first worm gear, a driven helical gear, a driving helical gear, a third motor, a transmission gear, a worm, a fourth gear, a fifth gear and a second worm gear, wherein the third motor is fixedly connected with a motor support and is arranged at one side inside the mechanism shell, an output shaft of the third motor is fixedly connected with the driving helical gear, the driving helical gear is meshed with the driven helical gear, and the driven helical gear is coaxially connected with the transmission gear and is used for being meshed with the middle part of the worm for transmission;

a first worm gear and a second worm gear are fixedly mounted at two end parts of the worm respectively, the first worm gear is meshed with a third gear, the third gear is sequentially meshed with the second gear and the first gear for transmission, and a gear at the lower part of the first gear is meshed with a first transmission gear for transmission of a first water pump impeller;

the second worm gear is meshed with a fourth gear, the fourth gear is meshed with a fifth gear, and a lower gear of the fifth gear is meshed with a second transmission gear and used for transmitting a second water pump impeller.

As a further improvement of the technical scheme of the invention, bearing seats for the rotation of the worm are arranged at the two ends of the worm far away from the transmission gear, and the bearing seats are connected with the mechanism shell, so that the worm does not shake during rotation, the transmission among all mechanism parts is smoother, and the phenomenon of tooth clamping is avoided.

As a further improvement of the technical scheme of the invention, the first gear, the second gear and the third gear are all arranged on a first gear connecting disc; fourth gear and fifth gear all install on the second gear connection pad for it is more steady reliable between the gear transmission, and it is more convenient to install, does benefit to dismantle the change.

As a further improvement of the technical scheme of the invention, the first water pump impeller and the second water pump impeller rotate in the same direction, so that water flow is formed, the surface area of the water flow is increased, and evaporation is accelerated.

As a further improvement of the technical scheme of the invention, a display screen and an input operation panel are installed on the surface of a box body of the controller, a power module is installed inside the box body of the controller, the power module is electrically connected with the controller and used for providing voltages with different levels, the display screen is electrically connected with the controller and is convenient for checking real-time data and working modes, the input operation panel is electrically connected with the controller and is convenient for manually selecting the working modes or manually operating, and a circuit board containing a main control unit is integrated inside the box body of the controller.

As a further improvement of the technical scheme of the invention, a bridge plate is arranged above the converging channel, and the bridge plate is a reticular plate, so that the bearing and water flow evaporation are facilitated during walking.

As a further improvement of the technical scheme of the invention, a water tank is arranged outside the wall body, the water tank is connected with a water pump and is communicated with the top of the wet curtain through a third water pipe, the bottom of the wet curtain is connected with a second water pipe, the second water pipe is connected with the first water pipe through a connector, the first water pipe is communicated with the water tank, and a hot air device is arranged on the side wall of the wall body and is used for increasing the indoor temperature when the indoor temperature is low.

As a further improvement of the technical scheme of the invention, the hot air device comprises a heating pipe and an air inlet device in the device.

As a further improvement of the technical scheme of the invention, a first motor and a second motor are respectively fixedly mounted on the roof close to the vent, the output end of the first motor is hinged to the first skylight plate, the output end of the second motor is hinged to the second skylight plate, the first skylight plate and the second skylight plate are arranged in a mirror image mode and are matched with the vent, the first motor is electrically connected with the output end of the controller, and the second motor is electrically connected with the output end of the controller.

A temperature and humidity automatic monitoring control method for a phytotron comprises the following steps:

(1) grouping setting: the first turbofan and the first motor are divided into a group and numbered to be used as an A group action mechanism, the second turbofan and the second motor are divided into a group and numbered to be used as a B group action mechanism, the negative pressure fan is numbered to be used as a C group action mechanism, the third motor is numbered to be used as a D group action mechanism, and the hot air device is numbered to be used as an E group action mechanism;

(2) the mode setting is carried out by the main control of each group, and the mode setting comprises three working modes which are switchable by a controller or a manual work, namely a light working mode, a half working mode and a full working mode: when the light working mode is set, the controller or the manual work can only control one of the group A action mechanism and the group B action mechanism to work, and simultaneously can manually select the group C action mechanism or the group E action mechanism to work in a matching way;

(3) and each group of action mechanisms is realized: the information collected by the temperature and humidity sensor is transmitted to the controller to automatically select the working mode, or the working mode can be manually selected by an input operation panel, the manual control selection level is higher than the controller control selection level, after the working mode is selected, the controller is linked with the equipment action of each working mode, and whether the group C action mechanism or the group E action mechanism is matched with the work or not is manually selected;

actual temperature and humidity through gathering temperature and humidity sensor and three temperature values and humidity value of group that the controller was preset contrast, if actual temperature and humidity have surpassed three group's scope values of presetting gradually, then open mild mode, half mode and full mode in proper order for adjust the humiture in the artificial climate room.

The driving mechanism arranged in the base station drives the first water pump impeller and the second water pump impeller to rotate respectively to drive water flow, so that the surface area of the water flow is increased, the evaporation intensity of the water flow is accelerated, and meanwhile, the driving mechanism is matched with the negative pressure fan, the hot air device and a proper turbofan to work in a coordinated mode so as to adjust the temperature and the humidity in a climate room and accelerate the air flow in the climate room, so that plant seedling culture or strains, microorganisms and the like can adapt to the drop change, and the problems of physiological function reduction and the like caused by direct air humidification through spraying or atomizing are solved;

through the cooperation between actuating mechanism gear and the worm, the worm both ends of keeping away from drive gear are installed and are supplied worm pivoted bearing frame for the worm can not produce when rotatory and rock, and the transmission is more smooth between each mechanism part, can not appear the latch phenomenon.

Drawings

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

FIG. 2 is an internal schematic view of the drive mechanism of the present invention;

FIG. 3 is a top view of the internal structure of the driving mechanism of the present invention;

FIG. 4 is a view of the mounting positions of the first and second water pump impellers of the present invention;

FIG. 5 is a control schematic of the mild mode of operation of the present invention;

FIG. 6 is a control schematic of the semi-operational mode of the present invention;

FIG. 7 is a full operating mode control schematic of the present invention;

reference numerals: the water heater comprises a base 1, a dark cabin 2, a water tank 3, a first water pipe 4, an adapter 5, a second water pipe 6, a wet curtain 7, a third water pipe 8, a wall 9, a roof 10, a first turbofan 11, a first ceiling panel 12, a first motor 13, a center sill 14, a second motor 15, a second ceiling panel 16, a suspension beam 17, a second turbofan 18, a negative pressure fan 19, a controller 20, a bridge panel 21, a hot air device 22, a communication channel 23, a driving mechanism 24, a base platform 25, a first water pump impeller 26, a second water pump impeller 27, a power module 28, a power supply 29, a temperature and humidity sensor 30, a relay 31, an electromagnetic valve 32, a display screen 33, an input operation panel 34, a first transmission gear 2401, a mechanism housing 2402, a first gear 2403, a second gear 2404, a third gear 2405, a first worm gear 2406, a driven helical gear 2407, a driving helical gear 2408, a third motor 2409, a motor 2410, a first gear connection disc 1, The transmission gear 2412, the worm 2413, the fourth gear 2414, the second gear connecting disc 2415, the fifth gear 2416, the second transmission gear 2417 and the second worm gear 2418.

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.

Embodiment 1, please refer to fig. 1 to 4, an automatic temperature and humidity monitoring and controlling device for a climatic chamber includes a substrate 1 having a wall 9 and a base 25, wherein a first turbofan 11, a second turbofan 18 and a temperature and humidity sensor 30 are mounted on a side wall of the wall 9, and a wet curtain 7 and a negative pressure fan 19 are respectively disposed on two sides of the wall 9 for increasing the humidity in the climatic chamber; a communicating channel 23 formed between the wall 9 and the base 25 at intervals and used for forming communicating water flow, a first water pump impeller 26 arranged in the middle of the communicating channel 23, and a second water pump impeller 27 arranged in the middle of the communicating channel 23; a controller 20 for collecting information and linking signals with climate room temperature and humidity control to provide multiple mode selection; the driving mechanism 24 arranged in the base station 25 is in gear transmission with the first water pump impeller 26 and the second water pump impeller 27 respectively, and is used for driving the first water pump impeller 26 and the second water pump impeller 27 to rotate so as to drive water flow; the signal input end of the controller 20 is electrically connected with the temperature and humidity sensor 30, the output end of the controller 20 is electrically connected with the first turbofan 11 through a relay 31, the output end of the controller 20 is electrically connected with the second turbofan 18 through the relay 31, and the output end of the controller 20 is electrically connected with the negative pressure fan 19 through an electromagnetic valve 32.

Preferably, the top of the wall 9 is a roof 10 provided with a vent, a suspension beam 17 is connected between the wall 9, and a middle beam 14 is connected between the suspension beam 17 and the roof 10 and used for supporting the roof 10.

Preferably, the base platform 25 is internally provided with a dark chamber 2 for providing a good environment for the growth and cultivation of light-resistant microorganisms or plants.

Preferably, the driving mechanism 24 includes a first gear 2403, a second gear 2404, a third gear 2405, a first worm gear 2406, a driven bevel gear 2407, a driving bevel gear 2408, a third motor 2409, a transmission gear 2412, a worm 2413, a fourth gear 2414, a fifth gear 2416 and a second worm gear 2418, wherein the third motor 2409 is fixedly connected with a motor support 2410 and is installed on one side inside the mechanism housing 2402, the third motor 2409 is electrically connected with the output end of the controller 20 through a relay 31, the output shaft of the third motor 2409 is fixedly connected with the driving bevel gear 2408, the driving bevel gear 2408 is meshed with the driven bevel gear 2407, and the driven bevel gear 2407 is coaxially connected with the transmission gear 2412 and is used for meshing transmission with the middle part of the worm 2413; a first worm gear 2406 and a second worm gear 2418 are fixedly mounted at two end parts of the worm 2413 respectively, the first worm gear 2406 is meshed with a third gear 2405, the third gear 2405 is sequentially meshed with the second gear 2404 and the first gear 2403 for transmission, and a lower gear of the first gear 2403 is meshed with the first transmission gear 2401 for transmission of the first water pump impeller 26; the second worm gear 2418 is meshed with a fourth gear 2414, the fourth gear 2414 is meshed with a fifth gear 2416, a lower gear of the fifth gear 2416 is meshed with a second transmission gear 2417 and used for transmitting a second water pump impeller 27, and the rotation directions of the first water pump impeller 26 and the second water pump impeller 27 are consistent.

Preferably, a display screen 33 and an input operation panel 34 are installed on the surface of the box body of the controller 20, a power module 28 is installed inside the box body of the controller 20, the power module 28 is electrically connected with the controller 20 and used for providing voltages with different levels, the power module 28 is electrically connected with a power supply 29 and an external electric control cabinet and used for providing a stable power supply, the display screen 33 is electrically connected with the controller 20, the input operation panel 34 is electrically connected with the controller 20, and a circuit board containing a main control unit is integrated inside the box body of the controller 20.

Preferably, a bridge plate 21 is arranged above the communicating channel 23, and the bridge plate 21 is a net plate, so that the bearing and the water flow evaporation are facilitated during walking.

Preferably, a water tank 3 is arranged outside the wall body 9, the water tank 3 is connected with a water pump and is communicated with the top of a wet curtain 7 through a third water pipe 8, the bottom of the wet curtain 7 is connected with a second water pipe 6, the second water pipe 6 is connected with a first water pipe 4 through an adapter 5, the first water pipe 4 is communicated with the water tank 3, and a hot air device 22 is arranged on the side wall of the wall body 9.

Preferably, the roof 10 close to the vent is fixedly provided with a first motor 13 and a second motor 15 respectively, the output end of the first motor 13 is hinged to the first skylight plate 12, the output end of the second motor 15 is hinged to the second skylight plate 16, the first skylight plate 12 and the second skylight plate 16 are arranged in a mirror image mode and are matched with the vent, the output ends of the first motor 13 and the controller 20 are electrically connected through a relay 31, and the output ends of the second motor 15 and the controller 20 are electrically connected through the relay 31.

Referring to fig. 5 to 7, the present invention further provides a control method based on the above device, where the control method includes the following steps:

(1) grouping setting: the first turbofan 11 and the first motor 13 are divided into a group and numbered as a group A action mechanism, the second turbofan 18 and the second motor 15 are divided into a group and numbered as a group B action mechanism, the negative pressure fan 19 is numbered as a group C action mechanism, the third motor 2409 is numbered as a group D action mechanism, and the hot air device 22 is numbered as a group E action mechanism;

(2) the mode setting is carried out by the main control of each group, and the mode setting comprises three working modes which are switchable by a controller or a manual work, namely a light working mode, a half working mode and a full working mode: when the light working mode is set, the controller or the manual work can only control one of the group A action mechanism and the group B action mechanism to work, and simultaneously can manually select the group C action mechanism or the group E action mechanism to work in a matching way;

(3) and each group of action mechanisms is realized: the information collected by the temperature and humidity sensor 30 is transmitted to the controller 20 to automatically select the working mode, or the working mode can be manually selected by the input operation panel 34, the manual control selection level is higher than the control selection level of the controller 20, after the working mode is selected, the controller 20 is linked with the equipment action of each working mode, and whether the group C action mechanism or the group E action mechanism is matched with the work or not is manually selected;

(4) actual temperature and humidity that gather through with temperature and humidity sensor 30 compare with three temperature values and humidity value of group that the controller was preset, if actual temperature and humidity have surpassed three group's scope values of presetting gradually, then open mild mode, half mode and full mode in proper order for adjust the humiture in the artificial climate room.

Example 2, please refer to fig. 2 and 3:

bearing seats for rotation of the worm 2413 are mounted at two ends of the worm 2413 far away from the transmission gear 2412, so that the worm cannot shake during rotation, transmission among all mechanism parts is smoother, and the phenomenon of tooth clamping cannot occur, as in the rest embodiment 1.

Example 3, please refer to fig. 2 and 3:

the first gear 2403, the second gear 2404 and the third gear 2405 are all arranged on a first gear connecting disc 2411; the fourth gear 2414 and the fifth gear 2416 are both installed on the second gear connecting disc 2415, so that the gear transmission is more stable and reliable, the installation is more convenient, the disassembly and the replacement are facilitated, and the rest of the structure is the same as that of the embodiment 1.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a humiture automatic monitoring controlling means for in artificial climate room which characterized in that includes:

the device comprises a base (1), wherein a wall body (9) and a base platform (25) are installed on the base (1), a first turbofan (11), a second turbofan (18) and a temperature and humidity sensor (30) are installed on the side wall of the wall body (9), a wet curtain (7) and a negative pressure fan (19) are respectively arranged on two sides of the wall body (9) and used for increasing humidity in a climate room, and a hot air device (22) is arranged on the side wall of the wall body (9);

the converging channel (23) is formed between the wall body (9) and the base platform (25) at intervals and is used for forming converging water flow;

a first water pump impeller (26) and a second water pump impeller (27), wherein the first water pump impeller (26) is arranged in the middle of the communicating channel (23), and the second water pump impeller (27) is arranged in the middle of the communicating channel (23);

the controller (20) is used for collecting information and linking signals with climate room temperature and humidity control to provide multiple mode selection;

the driving mechanism (24) is arranged in the base station (25), is in gear transmission with the first water pump impeller (26) and the second water pump impeller (27) respectively, and is used for driving the first water pump impeller (26) and the second water pump impeller (27) to rotate to drive water flow, wherein the driving mechanism (24) comprises a first gear (2403), a second gear (2404), a third gear (2405), a first worm gear (2406), a driven helical gear (2407), a driving helical gear (2408), a third motor (2409), a transmission gear (2412), a worm (2413), a fourth gear (2414), a fifth gear (2416) and a second worm gear (2418), the third motor (2409) is fixedly connected with a motor support (2410) and is arranged on one side inside the mechanism shell (2402), an output shaft of the third motor (2409) is fixedly connected with the driving helical gear (2408), and the driving helical gear (2408) is meshed with the driven helical gear (2407), the driven bevel gear (2407) is coaxially connected with the transmission gear (2412) and is used for meshing transmission with the middle part of the worm (2413); a first worm gear (2406) and a second worm gear (2418) are fixedly mounted at two end parts of the worm (2413) respectively, the first worm gear (2406) is meshed with a third gear (2405), the third gear (2405) is sequentially meshed with the second gear (2404) and the first gear (2403) for transmission, and a lower gear of the first gear (2403) is meshed with the first transmission gear (2401) for transmission of a first water pump impeller (26); the second worm gear (2418) is meshed with a fourth gear (2414), the fourth gear (2414) is meshed with a fifth gear (2416), and a lower gear of the fifth gear (2416) is meshed with a second transmission gear (2417) and is used for transmitting a second water pump impeller (27);

the controller is characterized in that a signal input end of the controller (20) is electrically connected with the temperature and humidity sensor (30), an output end of the controller (20) is electrically connected with the first turbofan (11), an output end of the controller (20) is electrically connected with the second turbofan (18), and an output end of the controller (20) is electrically connected with the negative pressure fan (19).

2. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: bearing seats for the worm (2413) to rotate are arranged at the two ends of the worm (2413) far away from the transmission gear (2412).

3. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: the first gear (2403), the second gear (2404) and the third gear (2405) are all arranged on a first gear connecting disc (2411); the fourth gear (2414) and the fifth gear (2416) are both arranged on the second gear connecting disc (2415), so that the gear transmission is more stable and reliable.

4. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: the first water pump impeller (26) and the second water pump impeller (27) rotate in the same direction.

5. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: the utility model discloses a power supply device, including controller (20), box surface mounting of controller (20) has display screen (33) and input operation panel (34), the box internally mounted of controller (20) has power module (28), power module (28) are connected with controller (20) electricity for provide the voltage of different levels, display screen (33) with controller (20) electricity is connected, input operation panel (34) with controller (20) electricity is connected.

6. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: a bridge plate (21) is arranged above the communicating channel (23), and the bridge plate (21) is a net plate.

7. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: the water tank (3) is arranged outside the wall body (9), the water tank (3) is connected with the water pump, the water pump is communicated with the top of the wet curtain (7) through a third water pipe (8), the bottom of the wet curtain (7) is connected with a second water pipe (6), the second water pipe (6) is connected with the first water pipe (4) through a connector (5), and the first water pipe (4) is communicated with the water tank (3).

8. The automatic temperature and humidity monitoring and control device for the artificial climate room according to claim 1, characterized in that: roof (10) that is close to the vent fixed mounting respectively has first motor (13) and second motor (15), first motor (13) output is articulated with first skylight board (12), second motor (15) output is articulated with second skylight board (16), first skylight board (12) and second skylight board (16) mirror image setting, all with the vent adaptation, first motor (13) are connected with controller (20) output electricity, second motor (15) are connected with controller (20) output electricity.

9. A control method based on the device of claim 1, characterized in that the control method comprises the following steps:

grouping setting: a first turbofan (11) and a first motor (13) are divided into a group and numbered as an A group action mechanism, a second turbofan (18) and a second motor (15) are divided into a group and numbered as a B group action mechanism, a negative pressure fan (19) is numbered as a C group action mechanism, a third motor (2409) is numbered as a D group action mechanism, and a hot air device (22) is numbered as an E group action mechanism;

the mode setting is carried out by the main control of each group, and the mode setting comprises three working modes which are switchable by a controller or a manual work, namely a light working mode, a half working mode and a full working mode: when the light working mode is set, the controller or the manual work can only control one of the group A action mechanism and the group B action mechanism to work, and simultaneously can manually select the group C action mechanism or the group E action mechanism to work in a matching way;

and each group of action mechanisms is realized: the information collected by the temperature and humidity sensor (30) is transmitted to the controller (20) to automatically select the working mode, or the working mode can be manually selected by the input operation panel (34), the manual control selection level is higher than the control selection level of the controller (20), after the working mode is selected, the controller (20) is linked with the equipment action of each working mode, and whether the group C action mechanism or the group E action mechanism is matched with the work or not is manually selected;

actual temperature and humidity that gather through with temperature and humidity sensor (30) compare with three temperature values and humidity value of group that the controller was preset, if actual temperature and humidity have surpassed three group's scope values of presetting gradually, then open mild mode, half mode and full mode in proper order for adjust the humiture in the artificial climate room.

Images