阅读说明：本技术 一种吊顶式新风除湿机高效除湿系统 (High-efficient dehumidification system of suspension type new trend dehumidifier ) 是由 袁润修 于 2020-05-29 设计创作，主要内容包括：本发明公开了空调设备技术领域的一种吊顶式新风除湿机高效除湿系统,包括新风除湿机,所述新风除湿机的内部包括除湿装置、新风进管、回风进管、送风出管、内盘管、压缩机、风机和微电脑处理器,所述新风进管和所述回风进管插接于所述新风除湿机的右侧壁；该吊顶式新风除湿机高效除湿系统的设置,结构设计合理,通过设计四种除湿模式,温度传感器、湿度传感器以及机组风道内的内盘管传感器变化情况控制电机的转速以及开停机,以实现正常除湿控制模式、低温除湿控制模式、容霜除湿模式和高温除湿控制模式的切换,从而使得在低温高湿和高温高湿状态下,能够对室内进行高效除湿并确保机组可靠性。(The invention discloses a high-efficiency dehumidification system of a ceiling type fresh air dehumidifier in the technical field of air conditioning equipment, which comprises a fresh air dehumidifier, wherein the fresh air dehumidifier internally comprises a dehumidification device, a fresh air inlet pipe, a return air inlet pipe, an air supply outlet pipe, an inner coil pipe, a compressor, a fan and a microcomputer processor, and the fresh air inlet pipe and the return air inlet pipe are inserted into the right side wall of the fresh air dehumidifier; this high-efficient dehumidification system of suspension type new trend dehumidifier's setting, structural design is reasonable, through designing four kinds of dehumidification modes, a weighing sensor and a temperature sensor, the rotational speed and the start-stop machine of interior coil pipe sensor situation of change control motor in humidity transducer and the unit wind channel, in order to realize normal dehumidification control mode, low temperature dehumidification control mode, the switching of appearance frost dehumidification mode and high temperature dehumidification control mode, thereby make under low temperature and high temperature and humidity state, can be to indoor high-efficient dehumidification and ensure the unit reliability.)

1. The utility model provides a high-efficient dehumidification system of suspension type new trend dehumidifier which characterized in that: the novel air conditioner comprises a fresh air dehumidifier (100), wherein the fresh air dehumidifier (100) comprises a dehumidifier (110), a fresh air inlet pipe (120), a return air inlet pipe (130), an air supply outlet pipe (140), an inner coil pipe (150), a compressor (160), a fan (170) and a microcomputer processor (180), the fresh air inlet pipe (120) and the return air inlet pipe (130) are inserted into the right side wall of the fresh air dehumidifier (100), a return air humidity sensor (131) and a return air temperature sensor (132) are embedded into the bottom of an inner cavity of the return air inlet pipe (130), the air supply outlet pipe (140) is inserted into the left side wall of the fresh air dehumidifier (100), an air supply temperature sensor (141) is embedded into the bottom of the inner cavity of the air supply outlet pipe (140), the inner coil pipe (150) and the compressor (160) are fixed on the top of the inner cavity of the fresh air dehumidifier (100) through, an inner coil sensor (151) is embedded in the front side wall of the inner coil (150), two ends of the fan (170) are respectively communicated with the dehumidifying device (110) and the air supply outlet pipe (140) through a fan cover (171), and the return air humidity sensor (131), the return air temperature sensor (132), the air supply temperature sensor (141) and the inner coil sensor (151) are electrically connected with the microcomputer processor (180) in an output mode;

the dehumidification mode is as follows:

normal dehumidification control mode: the return air humidity sensor (131) is positioned at the return air inlet and transmits data to the microcomputer processor through a lead;

low-temperature dehumidification control mode: the return air temperature sensor (132) is positioned at the return air inlet and transmits data to the microcomputer processor through a lead;

and (3) a frost-containing dehumidification mode: the air supply temperature sensor (141) is positioned at the air supply port and transmits data to the microcomputer processor through a lead;

high-temperature dehumidification control mode: the inner coil sensor (151) is positioned on the outer side wall of the inner coil, and the temperature sensor transmits data to the microcomputer processor through a lead;

the electrical output of the microcomputer processor is connected with the motor.

2. The efficient dehumidification system of a suspended ceiling type fresh air dehumidifier as claimed in claim 1, wherein: normal dehumidification control mode: TS-TSD is less than or equal to 0%: stopping the compressor, stopping the fan for 60 seconds, and starting the compressor when the TS-TSD is more than 3%;

when TA is less than 0 ℃, the compressor stops working, the air valve is closed, the fan operates at low wind speed reduced by 100 revolutions, and the normal operation is recovered when TA is more than or equal to 2 ℃;

when TA is less than or equal to 17 ℃, dehumidifying for 32 minutes as a period, operating the compressor for 24 minutes, and stopping the compressor for 8 minutes;

after the compressor is started and continuously operates for 5 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, after 10 minutes, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, and the compressor operates for 15 minutes and then resumes the set wind operation;

when TA is more than 17 ℃ and less than or equal to 24 ℃, dehumidifying for 50 minutes as a period, operating the compressor for 45 minutes, and stopping for 5 minutes;

after the compressor is started and continuously operates for 15 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 7 minutes, and the compressor operates for 20 minutes and then resumes the set wind operation;

TA is more than 24 ℃ and less than or equal to 30 ℃, the compressor is normal, and the fan works according to the set wind speed;

TA is higher than 30 ℃, the compressor is normal, and the fan forces high wind to operate;

(1) when the current fan rotating speed is the lowest gear or TC is more than 35 ℃, the downshifting processing is not executed, and the temperature zone is switched to have a return difference of 1 ℃ so as to prevent frequent starting and switching;

(2) when a shutdown signal is received, the compressor stops → 10 seconds later, the fan stops, and the air valve is closed;

(3) when the air valve is not opened in the starting state, when the unit is started and operates for 7 hours and 50 minutes cumulatively, and the return air humidity is less than or equal to 50 percent, the air valve is opened for 10 minutes and then closed, the circulation is carried out for 8 hours in a period, and the on-off requirement of the wire controller is executed when a wire controller on-off signal is received in the period.

3. The efficient dehumidification system of a suspended ceiling type fresh air dehumidifier as claimed in claim 1, wherein: low-temperature dehumidification control mode:

(1) the compressor of the unit is started and operates for 7 minutes, the TA temperature is memorized, and the TA difference value is calculated after 7 minutes (after 7 minutes, before 7 minutes is subtracted);

(2) when the TA difference value is more than or equal to 0 ℃, the normal operation of the unit is carried out, the current fan rotating speed is reduced by one gear at the temperature of less than-2 ℃, and then the judgment is carried out once every 20 minutes until the fan rotating speed is reduced to the lowest gear;

(3) when the TA difference is less than-4 deg.c, the compressor is stopped, the blower is operated at the lowest rotation speed, and when the TA difference is greater than or equal to 0 deg.c, the compressor is started.

4. The efficient dehumidification system of a suspended ceiling type fresh air dehumidifier as claimed in claim 1, wherein: and (3) a frost-containing dehumidification mode:

(1) when TE temperature is detected to be less than-5 ℃ and the running time of the compressor lasts for more than 20 minutes, the frost accommodating operation is carried out (if the air valve is in an open state, the air valve is forcibly closed); gradually switching the fan to a low wind gear for 7 minutes (the wind gear switching interval is 10 seconds), reducing the rotating speed of 100 again for 5 minutes after 7 minutes on the basis of low wind gear, and when the TE temperature is lower than-10 ℃, stopping the compressor, and operating the fan according to the current rotating speed;

(2) when the TE temperature is more than or equal to 0 ℃, the compressor is started to normally operate, and the air valve is restored to the state before protection.

5. The efficient dehumidification system of a suspended ceiling type fresh air dehumidifier as claimed in claim 1, wherein: high-temperature dehumidification control mode: when the TC temperature is more than or equal to 38 ℃ and more than 35 ℃, the fan forces the high-wind gear to operate, when the TC temperature is more than or equal to 43 ℃, the fan forces the high-wind gear and adds 100 revolutions on the basis of the high wind rotating speed, and when the TC temperature is more than or equal to 48 ℃, the fan forces the high-wind gear and adds 200 revolutions on the basis of the high wind rotating speed.

Technical Field

The invention relates to the technical field of air conditioning equipment, in particular to a high-efficiency dehumidification system of a ceiling type fresh air dehumidifier.

Background

After the fresh air dehumidifier filters and dehumidifies outdoor air, the air which is relatively dry and reaches the target relative humidity is delivered to the indoor space through the fresh air pipeline, so that the requirement of comfort or process indoor environment humidity is met. The dehumidified air is generally used in indoor locations where air purification is required. The existing dehumidifier has a serious problem that only a single dehumidification mode is adopted when the dehumidifier is used, so that indoor humidity cannot be efficiently dehumidified when the indoor humidity environment is complex, and a high-efficiency dehumidification system of a ceiling type fresh air dehumidifier is provided for the purpose.

Disclosure of Invention

The invention aims to provide a high-efficiency dehumidification system of a ceiling type fresh air dehumidifier, which aims to solve the problem that the dehumidifier provided by the background technology only has a single dehumidification mode when in use, so that the indoor dehumidification cannot be efficiently carried out when the indoor humidity environment is complex.

In order to achieve the purpose, the invention provides the following technical scheme: the high-efficiency dehumidification system of the ceiling type fresh air dehumidifier comprises a fresh air dehumidifier, wherein the fresh air dehumidifier is internally provided with a dehumidification device, a fresh air inlet pipe, a return air inlet pipe, an air supply outlet pipe, an inner coil pipe, a compressor, a fan and a microcomputer processor, the fresh air inlet pipe and the return air inlet pipe are inserted into the right side wall of the fresh air dehumidifier, the bottom of the inner cavity of the return air inlet pipe is embedded with a return air humidity sensor and a return air temperature sensor, the air supply outlet pipe is inserted into the left side wall of the fresh air dehumidifier, the bottom of the inner cavity of the air supply outlet pipe is embedded with an air supply temperature sensor, the inner coil pipe and the compressor are fixed at the top of the inner cavity of the fresh air dehumidifier through bolts, the front side wall of the inner coil pipe is embedded with an inner coil pipe sensor, two ends of the fan are respectively communicated with the dehumidification, The return air temperature sensor, the air supply temperature sensor and the inner coil sensor are all electrically connected with the microcomputer processor,

the dehumidification mode is as follows:

normal dehumidification control mode: the return air humidity sensor is positioned at the return air inlet and transmits data to the microcomputer processor through a lead;

low-temperature dehumidification control mode: the air return temperature sensor is positioned at the air return opening and transmits data to the microcomputer processor through a lead;

and (3) a frost-containing dehumidification mode: the air supply temperature sensor is positioned at the air supply port and transmits data to the microcomputer processor through a lead;

high-temperature dehumidification control mode: the inner coil sensor is positioned on the outer side wall of the inner coil, and the temperature sensor transmits data to the microcomputer processor through a lead;

the electrical output of the microcomputer processor is connected with the motor.

Preferably, the normal dehumidification control mode: TS-TSD is less than or equal to 0%: stopping the compressor, stopping the fan for 60 seconds, and starting the compressor when the TS-TSD is more than 3%;

when TA is less than 0 ℃, the compressor stops working, the air valve is closed, the fan operates at low wind speed reduced by 100 revolutions, and the normal operation is recovered when TA is more than or equal to 2 ℃;

when TA is less than or equal to 17 ℃, dehumidifying for 32 minutes as a period, operating the compressor for 24 minutes, and stopping the compressor for 8 minutes;

after the compressor is started and continuously operates for 5 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, after 10 minutes, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, and the compressor operates for 15 minutes and then resumes the set wind operation;

when TA is more than 17 ℃ and less than or equal to 24 ℃, dehumidifying for 50 minutes as a period, operating the compressor for 45 minutes, and stopping for 5 minutes;

after the compressor is started and continuously operates for 15 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 7 minutes, and the compressor operates for 20 minutes and then resumes the set wind operation;

TA is more than 24 ℃ and less than or equal to 30 ℃, the compressor is normal, and the fan works according to the set wind speed;

TA is higher than 30 ℃, the compressor is normal, and the fan forces high wind to operate;

(1) when the current fan rotating speed is the lowest gear or TC is more than 35 ℃, the downshifting processing is not executed, and the temperature zone is switched to have a return difference of 1 ℃ so as to prevent frequent starting and switching;

(2) when a shutdown signal is received, the compressor stops → 10 seconds later, the fan stops, and the air valve is closed;

(3) when the air valve is not opened in the starting state, when the unit is started and operates for 7 hours and 50 minutes cumulatively, and the return air humidity is less than or equal to 50 percent, the air valve is opened for 10 minutes and then closed, the circulation is carried out for 8 hours in a period, and the on-off requirement of the wire controller is executed when a wire controller on-off signal is received in the period.

Preferably, the low-temperature dehumidification control mode:

(1) the compressor of the unit is started and operates for 7 minutes, the TA temperature is memorized, and the TA difference value is calculated after 7 minutes (after 7 minutes, before 7 minutes is subtracted);

(2) when the TA difference value is more than or equal to 0 ℃, the normal operation of the unit is carried out, the current fan rotating speed is reduced by one gear at the temperature of less than-2 ℃, and then the judgment is carried out once every 20 minutes until the fan rotating speed is reduced to the lowest gear;

(3) when the TA difference is less than-4 deg.c, the compressor is stopped, the blower is operated at the lowest rotation speed, and when the TA difference is greater than or equal to 0 deg.c, the compressor is started.

Preferably, the frost-containing dehumidification mode is as follows:

(1) when TE temperature is detected to be less than-5 ℃ and the running time of the compressor lasts for more than 20 minutes, the frost accommodating operation is carried out (if the air valve is in an open state, the air valve is forcibly closed); gradually switching the fan to a low wind gear for 7 minutes (the wind gear switching interval is 10 seconds), reducing the rotating speed of 100 again for 5 minutes after 7 minutes on the basis of low wind gear, and when the TE temperature is lower than-10 ℃, stopping the compressor, and operating the fan according to the current rotating speed;

(2) when the TE temperature is more than or equal to 0 ℃, the compressor is started to normally operate, and the air valve is restored to the state before protection.

Preferably, the high temperature dehumidification control mode: when the TC temperature is more than or equal to 38 ℃ and more than 35 ℃, the fan forces the high-wind gear to operate, when the TC temperature is more than or equal to 43 ℃, the fan forces the high-wind gear and adds 100 revolutions on the basis of the high wind rotating speed, and when the TC temperature is more than or equal to 48 ℃, the fan forces the high-wind gear and adds 200 revolutions on the basis of the high wind rotating speed.

Compared with the prior art, the invention has the beneficial effects that: this high-efficient dehumidification system of suspension type new trend dehumidifier's setting, structural design is reasonable, through designing four kinds of dehumidification modes, a weighing sensor and a temperature sensor, the rotational speed and the start-stop machine of interior coil pipe sensor situation of change control motor in humidity transducer and the unit wind channel, in order to realize normal dehumidification control mode, low temperature dehumidification control mode, the switching of appearance frost dehumidification mode and high temperature dehumidification control mode, thereby make under low temperature and high temperature and humidity state, can be to indoor high-efficient dehumidification and ensure the unit reliability.

Drawings

FIG. 1 is a schematic view of the internal structure of the present invention.

In the figure: the fresh air dehumidifier 100, the dehumidifier 110, the fresh air inlet pipe 120, the return air inlet pipe 130, the return air humidity sensor 131, the return air temperature sensor 132, the air supply outlet pipe 140, the air supply temperature sensor 141, the inner coil 150, the inner coil sensor 151, the compressor 160, the fan 170, the fan cover 171 and the microcomputer processor 180.

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.

The invention provides a high-efficiency dehumidification system of a ceiling type fresh air dehumidifier, which comprises a fresh air dehumidifier, wherein the interior of the fresh air dehumidifier 100 comprises a dehumidification device 110, a fresh air inlet pipe 120, a return air inlet pipe 130, an air supply outlet pipe 140, an inner coil 150, a compressor 160, a fan 170 and a microcomputer processor 180, the fresh air inlet pipe 120 and the return air inlet pipe 130 are inserted into the right side wall of the fresh air dehumidifier 100, the bottom of the inner cavity of the return air inlet pipe 130 is embedded with a return air humidity sensor 131 and a return air temperature sensor 132, the air supply outlet pipe 140 is inserted into the left side wall of the fresh air dehumidifier 100, the bottom of the inner cavity of the air supply outlet pipe 140 is embedded with an air supply temperature sensor 141, the inner coil 150 and the compressor 160 are fixed on the top of the inner cavity of the fresh air dehumidifier 100 through bolts, the front side wall of the inner coil 150 is embedded with, the return air humidity sensor 131, the return air temperature sensor 132, the air supply temperature sensor 141 and the inner coil sensor 151 are electrically connected with the microcomputer processor 180 in output;

the dehumidification mode is as follows:

normal dehumidification control mode: the return air humidity sensor is positioned at the return air inlet and transmits data to the microcomputer processor through a lead;

low-temperature dehumidification control mode: the air return temperature sensor is positioned at the air return opening and transmits data to the microcomputer processor through a lead;

and (3) a frost-containing dehumidification mode: the air supply temperature sensor is positioned at the air supply port and transmits data to the microcomputer processor through a lead;

high-temperature dehumidification control mode: the inner coil sensor is positioned on the outer side wall of the inner coil, and the temperature sensor transmits data to the microcomputer processor through a lead;

the electrical output of the microcomputer processor is connected with the motor.

Normal dehumidification control mode: TS-TSD is less than or equal to 0%: stopping the compressor, stopping the fan for 60 seconds, and starting the compressor when the TS-TSD is more than 3%;

when TA is less than 0 ℃, the compressor stops working, the air valve is closed, the fan operates at low wind speed reduced by 100 revolutions, and the normal operation is recovered when TA is more than or equal to 2 ℃;

when TA is less than or equal to 17 ℃, dehumidifying for 32 minutes as a period, operating the compressor for 24 minutes, and stopping the compressor for 8 minutes;

after the compressor is started and continuously operates for 5 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, after 10 minutes, the rotating speed of the current fan is reduced by one gear to operate for 5 minutes, and the compressor operates for 15 minutes and then resumes the set wind operation;

when TA is more than 17 ℃ and less than or equal to 24 ℃, dehumidifying for 50 minutes as a period, operating the compressor for 45 minutes, and stopping for 5 minutes;

after the compressor is started and continuously operates for 15 minutes in the current period, the rotating speed of the current fan is reduced by one gear to operate for 7 minutes, and the compressor operates for 20 minutes and then resumes the set wind operation;

TA is more than 24 ℃ and less than or equal to 30 ℃, the compressor is normal, and the fan works according to the set wind speed;

TA is higher than 30 ℃, the compressor is normal, and the fan forces high wind to operate;

(1) when the current fan rotating speed is the lowest gear or TC is more than 35 ℃, the downshifting processing is not executed, and the temperature zone is switched to have a return difference of 1 ℃ so as to prevent frequent starting and switching;

(2) when a shutdown signal is received, the compressor stops → 10 seconds later, the fan stops, and the air valve is closed;

(3) when the air valve is not opened in the starting state, when the unit is started and operates for 7 hours and 50 minutes cumulatively, and the return air humidity is less than or equal to 50 percent, the air valve is opened for 10 minutes and then closed, the circulation is carried out for 8 hours in a period, and the on-off requirement of the wire controller is executed when a wire controller on-off signal is received in the period.

Low-temperature dehumidification control mode:

(1) the compressor of the unit is started and operates for 7 minutes, the TA temperature is memorized, and the TA difference value is calculated after 7 minutes (after 7 minutes, before 7 minutes is subtracted);

(2) when the TA difference value is more than or equal to 0 ℃, the normal operation of the unit is carried out, the current fan rotating speed is reduced by one gear at the temperature of less than-2 ℃, and then the judgment is carried out once every 20 minutes until the fan rotating speed is reduced to the lowest gear;

(3) when the TA difference is less than-4 deg.c, the compressor is stopped, the blower is operated at the lowest rotation speed, and when the TA difference is greater than or equal to 0 deg.c, the compressor is started.

And (3) a frost-containing dehumidification mode:

(1) when TE temperature is detected to be less than-5 ℃ and the running time of the compressor lasts for more than 20 minutes, the frost accommodating operation is carried out (if the air valve is in an open state, the air valve is forcibly closed); gradually switching the fan to a low wind gear for 7 minutes (the wind gear switching interval is 10 seconds), reducing the rotating speed of 100 again for 5 minutes after 7 minutes on the basis of low wind gear, and when the TE temperature is lower than-10 ℃, stopping the compressor, and operating the fan according to the current rotating speed;

(2) when the TE temperature is more than or equal to 0 ℃, the compressor is started to normally operate, and the air valve is restored to the state before protection.

High-temperature dehumidification control mode: when the TC temperature is more than or equal to 38 ℃ and more than 35 ℃, the fan forces the high-wind gear to operate, when the TC temperature is more than or equal to 43 ℃, the fan forces the high-wind gear and adds 100 revolutions on the basis of the high wind rotating speed, and when the TC temperature is more than or equal to 48 ℃, the fan forces the high-wind gear and adds 200 revolutions on the basis of the high wind rotating speed.

TA indoor ambient temperature (return air temperature sensor), TS indoor ambient humidity (return air humidity sensor), TE indoor evaporator coil temperature (inner coil sensor), TC: supply air cavity temperature (supply air temperature sensor), TSD: the humidity is set.

The working principle is as follows: indoor air is sucked into the dehumidifier 110 from the return air inlet pipe 130 under the action of the compressor 160, the return air humidity sensor 131 and the return air temperature sensor 132 acquire the temperature and humidity of the entering air, the air is dehumidified by the dehumidifier 110 and the inner coil 150 and then enters the air outlet pipe 140 through the fan cover 171 under the action of the fan 170 and is sent into the room, the air supply temperature sensor 141 acquires the temperature of the supplied air, the return air humidity sensor 131, the return air temperature sensor 132, the air supply temperature sensor 141 and the inner coil sensor 151 transmit information to the microcomputer processor 180, the microcomputer processor 180 performs rapid analysis according to the acquired data, and an optimal dehumidification mode is selected from four dehumidification modes (a normal dehumidification control mode, a low temperature dehumidification control mode and a frost containing dehumidification mode), and further dehumidifies the air absorbed in the room.

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.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the various features of the embodiments disclosed herein may be used in any combination, provided that there is no structural conflict, and the combinations are not exhaustively described in this specification merely for the sake of brevity and conservation of resources. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.