CN105066350A - Temperature control device, temperature adjusting system and temperature control method - Google Patents

Abstract

The invention discloses a temperature control device, a temperature adjusting system and a temperature control method. The temperature control device comprises a wireless signal transceiver and a controller. The wireless signal transceiver transmits activation signals to a passive temperature sensor, receives returned signals transmitted by the activated passive temperature sensor and transmits the returned signals to the controller. The controller generates temperature control signals based on the returned signals. According to the scheme, the temperature control granularity within the preset space range can be more accurate.

Description

Temperature control equipment, humidity control system and temperature-controlled process

Technical field

The disclosure relates generally to Smart Home field, is specifically related to the Based Intelligent Control of temperature, particularly relates to temperature control equipment, humidity control system and temperature-controlled process.

Background technology

In housed device, air-conditioning is one of electrical equipment the most frequently used, is no matter hot environment or the region of cold, and air-conditioning has important effect for providing a comfortable living environment.

Because the air-conditioning position of daily installation is relatively-stationary, when when a larger room using air-condition, the temperature at diverse location place can be uneven.For example, in some scenes, suppose that arranging air-conditioning is steady temperature, the pattern of evenly sweeping wind, then distance air-conditioning temperature ratio is nearby at a distance closer to setting value.In other scenes, if certain location personnel is assembled more in room, possible temperature can be relatively high, and certain location personnel assembles less possibility temperature can be relatively low.

Air-conditioning cannot know the actual temperature value of each position, room, and adjusts according to actual temperature value.

Summary of the invention

In view of above-mentioned defect of the prior art or deficiency, expect to provide a kind of temperature control equipment, humidity control system and temperature-controlled process, the temperature information that can sensor-basedly return generates the temperature control signals corresponding to the position of sensor.

First aspect, the embodiment of the present application provides a kind of temperature control equipment, comprises wireless signal transceiver and controller; Wherein: wireless signal transceiver sends activation signal to passive temperature sensor, receive the inverse signal of the passive temperature sensor transmission be activated, and inverse signal is sent to controller; Controller generates temperature control signals based on inverse signal.

Second aspect, the embodiment of the present application additionally provides a kind of humidity control system, comprises at least one passive temperature sensor, temperature control equipment and temperature-adjusting device; Wherein: passive temperature sensor gathers Current Temperatures information and is sent to temperature control equipment; Temperature control equipment generates temperature control signals based on Current Temperatures information and temperature control signals is sent to temperature-adjusting device; Temperature-adjusting device carries out temperature adjustment based on temperature control signals.

The third aspect, the embodiment of the present application additionally provides a kind of temperature-controlled process, comprising: send activation signal to passive temperature sensor; Receive the inverse signal of the passive temperature sensor transmission be activated; And generate temperature control signals based on the temperature information in inverse signal and sensor orientation information.

The embodiment of the present application provide scheme, according to the position of passive temperature sensor and the Current Temperatures information of sensing thereof, generate temperature signal, make the temperature Control granularity within the scope of predetermined space more accurate.

In some implementations of the application, surface acoustic wave sensor is adopted to be used as passive temperature sensor, and the mark of surface acoustic wave sensor is determined by the different arrangement modes of reflecting grating, in conjunction with the temperature information comprised in the inverse signal of surface acoustic wave sensor, the position of surface acoustic wave sensor in predetermined space can be determined, thus for temperature fine granularity control reference is provided.

In some implementations of the application, can also by surface acoustic wave sensor being arranged on human body and/or portable electric appts, carry out the Current Temperatures information of environment near corresponding collection user, thus the Current Temperatures information that temperature control equipment can be made to gather based on these surface acoustic wave sensors regulates thermostatic output, the target temperature of the environment temperature around user and its setting is matched.

Accompanying drawing explanation

By reading the detailed description done non-limiting example done with reference to the following drawings, the other features, objects and advantages of the application will become more obvious:

Fig. 1 shows the schematic diagram of the temperature control equipment according to the application's embodiment;

Fig. 2 shows the schematic diagram of the humidity control system according to the application's embodiment;

Fig. 3 shows the schematic diagram of the surface acoustic wave sensor according to the application's embodiment;

Fig. 4 shows the schematic diagram of a kind of application scenarios of the humidity control system according to the application's embodiment;

Fig. 5 shows in the application scenarios of Fig. 4, and humidity control system carries out thermoregulator indicative flowchart;

Fig. 6 shows the indicative flowchart of the temperature-controlled process according to the application's embodiment.

Detailed description of the invention

Below in conjunction with drawings and Examples, the application is described in further detail.Be understandable that, specific embodiment described herein is only for explaining related invention, but not the restriction to this invention.It also should be noted that, for convenience of description, illustrate only in accompanying drawing and invent relevant part.

It should be noted that, when not conflicting, the embodiment in the application and the feature in embodiment can combine mutually.Below with reference to the accompanying drawings and describe the application in detail in conjunction with the embodiments.

Realize the control of fine-grained temperature in order to solve to the different azimuth of predetermined space, existing solution is at room set temperature sensor at present, then temperature value is transmitted back temperature-adjusting device.But sensor needs supply line or extra battery in this solution.

In addition, also have in some solutions, by installation infrared scanning means in temperature-adjusting device, and utilize noctovisor scan to carry out temperature detection.But this solution due to the sweep limits of noctovisor scan limited, have certain limitation.

The temperature control equipment of the application, humidity control system and temperature-controlled process are intended to solve at least one technical problem as above.

As shown in Figure 1, be schematic structure Figure 100 of the temperature control equipment of the embodiment of the present application.

Temperature control equipment comprises wireless signal transceiver 110 and controller 120.

Wireless signal transceiver 110 sends activation signal to passive temperature sensor, receives the inverse signal of the passive temperature sensor transmission be activated, and inverse signal is sent to controller 120.

The inverse signal that controller 120 receives based on wireless signal transceiver 110 generates temperature control signals.

As is known to the person skilled in the art, passive device can work when there being signal without the need to adding power supply.Therefore, in order to enable passive temperature sensor collecting temperature information, activation signal can be sent to it, making passive temperature sensor enter duty.

In some implementations, activation signal can be such as radiofrequency signal.

Passive temperature sensor, after receiving activation signal, can generate the inverse signal relevant to environment temperature, and controller 120 can obtain the temperature generation temperature control signals of passive temperature sensor place environment based on this inverse signal.

In some implementations, in controller 120, target temperature information can be previously stored with, and the deviation between the temperature information collected according to passive temperature sensor and target temperature information generates temperature control signals.

In other implementations, can also be previously stored with temperature difference information in controller 120, the temperature information that controller 120 collects according to passive temperature sensor and temperature difference information, generate temperature control signals.

Such as, in the application scenes of these implementations, based on the consideration to health, carry out temperature and regulate forward and backward temperature difference can control within a certain temperature value or temperature range (such as, temperature difference is no more than 6 degrees Celsius).In these application scenarios, ambient temperature can be gathered by passive temperature sensor, temperature difference information is prestored in controller 120, and carry out corresponding output temperature control signal based on the temperature information that passive temperature sensor collects, thus the difference controlling Current Temperatures and ambient temperature is no more than default temperature difference.

In some implementations, temperature control equipment can send activation signal to more than a passive temperature sensor, and receives their inverse signal.

In these implementations, in the inverse signal of passive temperature sensor except can comprising the temperature information of its sensing, its identification information can also be comprised.Controller 120 can obtain the identification information of passive temperature sensor and the temperature information of sensing by resolving inverse signal, and generates temperature control signals based on the temperature information sensed and target temperature information.

Such as, the identification information of passive temperature sensor of controller 120 by parsing, can form the mark of passive temperature sensor and the corresponding relation of its temperature collected, that is to say, controller 120 can learn that it receives temperature information and derives from which passive temperature sensor.

Controller 120 can also generate temperature control signals based on the difference of the temperature information of sensing and target information.Controller 120 such as can the control mode of adoption rate-Integrated Derivative (ProportionalIntegralDifferential, PID), or, the control modes such as PD, the PI in PID can also be adopted to generate control signal.

In some implementations, controller 120 can also obtain thermostatic wind direction information.Corresponding relation based on the temperature information of wind direction and sensing judges the orientation of passive temperature sensor.

Under normal circumstances, during temperature-adjusting device work, temperature adjustment can be carried out with fixing wind direction, also can make wind direction dynamic change at work, carry out temperature adjustment.Such as, can come in a stepping manner to carry out " sweeping wind " in certain angle scope (such as 0 ° ~ 180 ° scopes).

Can predict, when passive temperature sensor is in the orientation corresponding with current wind direction, compared with other passive temperature sensors, the temperature that this passive temperature sensor corresponding with current wind direction collects is closer to target temperature.Therefore, based on the corresponding relation of the temperature information that this wind direction and passive temperature sensor sense, the orientation of passive temperature sensor can be known.

In these implementations, owing to obtaining the azimuth information of passive temperature sensor, the fine granularity that controller can carry out temperature controls.Such as, when the inverse signal of a certain passive temperature sensor points out its region and target temperature difference is larger, the retention time of the wind direction corresponding with the orientation of this passive temperature sensor can be increased by temperature control signals, make the inverse signal of this passive temperature sensor point out its region to reach target temperature, then change thermostatic wind direction; Or, can also wind direction to should the orientation of passive temperature sensor time, increase thermostatic air quantity; Or, can also wind direction to should the orientation of passive temperature sensor time, realize the quick tracking target temperature of actual temperature of current region by reducing/raising target temperature.

In some implementations, the position of multiple passive temperature sensor can be known, such as, before temperature control equipment starts output temperature control signal, has obtained the positional information of each passive temperature sensor.

In the application scenes of these implementations, the distance between each passive temperature sensor may be greater than predetermined threshold value.In these application scenarios, the temperature information of the sensing of each passive temperature sensor that controller 120 can be resolved based on it generates the temperature control signals corresponding to this passive temperature sensing station, thus can carry out fine-grained temperature control to each corresponding region of passive temperature sensor.

In other application scenarios of these implementations, the distance between part passive temperature sensor may be less than predetermined threshold value.In these application scenarios, the temperature information of the sensing of each passive temperature sensor in this predetermined threshold range that controller 120 can be resolved based on it determines temperature averages in the region corresponding with this predetermined threshold range, and based on the temperature control signals in this temperature averages determination predetermined threshold range.

In some implementations, target temperature information such as can be determined based at least one item in user health situation, history target temperature data and indoor and outdoor temperature difference.

In the application scenes of these implementations, such as, target temperature is determined based on user health situation.In these application scenarios, the user health data that the wearable device that controller 120 can accept user gathers, such as heart rate, quantity of perspiration etc., and the target temperature being suitable for this user is calculated according to user health data.

In other application scenarios of these implementations, such as, target temperature can also be determined based on history target temperature data.In these application scenarios, the target temperature that certain user was arranged on a certain date and/or time period can be stored in controller 120, control 120 and based on the history target temperature data matched with current date and/or time period in these history target temperature data, and current target temperature information can be set.

In other application scenarios of these implementations, such as, target temperature can also be determined based on indoor and outdoor temperature difference.In these application scenarios, if when indoor and outdoor temperature difference exceedes predetermined threshold, the temperature control signals that adjustable controller 120 exports, thus the temperature difference reducing indoor and outdoor makes it close to predetermined threshold.On the other hand, if when indoor and outdoor temperature difference is much smaller than predetermined threshold, also can adjust the temperature control signals that controller 120 exports, thus increase indoor and outdoor temperature official post close to predetermined threshold.

As shown in Figure 2, be schematic structure Figure 200 of the humidity control system of the embodiment of the present application.

A kind of humidity control system comprises at least one passive temperature sensor 220, temperature control equipment 210 and temperature-adjusting device 230.

Passive temperature sensor 220 gathers Current Temperatures information and is sent to temperature control equipment 210.

Temperature control equipment 210 generates temperature control signals based on Current Temperatures information and temperature control signals is sent to temperature-adjusting device 230.Here, the concrete structure of temperature control equipment 210 temperature control equipment 100 that can describe in reference diagram 1.

Temperature-adjusting device 230 carries out temperature adjustment based on temperature control signals.

Passive temperature sensor 220 receives the activation signal that temperature control equipment 210 sends, and generates corresponding inverse signal and send to temperature control equipment 210.The Current Temperatures information of this passive temperature sensor 220 present position is contained in inverse signal.

In some implementations, passive temperature sensor 220 such as can comprise surface acoustic wave sensor.

As shown in Figure 3, be the schematic diagram 300 of the surface acoustic wave sensor according to the application's embodiment.

Surface acoustic wave sensor can comprise antenna 310, interdigital transducer 330, piezoelectric 320 and reflecting grating 340 etc.The antenna 310 of surface acoustic wave sensor can receive outside (such as, by temperature control equipment 210) radiofrequency signal that sends, interdigital transducer 330 converts radiofrequency signal to surface acoustic wave, propagate on piezoelectric 320 surface, after running into reflecting grating 340, surface acoustic wave is reflected, and returns interdigital transducer 330, then returns from antenna 310 transmitting.So realize passive response and the radio transmission of signal.Because do not need Power supply, the use of surface acoustic wave sensor can not be limited to layout and the issue for battery life of supply network.

The temperature sense function of surface acoustic wave sensor is by piezoelectric 320 pairs of responsive to temperatures, and its characteristic varies with temperature and changes to realize.Variations in temperature causes the characteristics such as the velocity of wave of the surface acoustic wave propagated on piezoelectric 320 surface or frequency to change, these changes are all back in temperature control equipment 210 by inverse signal, and as the foundation of temperature control equipment 210 output temperature control signal.

In some implementations, humidity control system can comprise the surface acoustic wave sensor of more than two.In order to make temperature control equipment 210 identify each surface acoustic wave sensor 220, such as, can arrange the reflecting grating quantity on surface acoustic wave sensor 220, the reflecting grating quantity that each surface acoustic wave sensor 220 is had is different.

Or, when humidity control system comprises the surface acoustic wave sensor of more than two, each surface acoustic wave sensor 220 is identified in order to make temperature control equipment 210, spacing on surface acoustic wave sensor 220 between each reflecting grating such as can also be set, make each surface acoustic wave sensor 220 have different reflecting grating spacing.

Continue with reference to figure 3.The antenna 310 of surface acoustic wave sensor receives a radiofrequency signal, surface acoustic wave is changed at interdigital transducer 330, and propagate into reflecting grating 340 on piezoelectric 320 surface, run into first reflecting grating, an inverse signal can be reflected, run into second reflecting grating, second inverse signal can be reflected, the like.These inverse signals convert radiofrequency signal to through interdigital transducer 330 again, and are launched by antenna 310.Because each reflecting grating 340 is different from the distance of interdigital transducer 330, so the inverse signal of each reflecting grating 340 is poor if having time, such one group of inverse signal just defines a group coding.

Therefore, by changing the quantity of reflecting grating and/or the position (such as, adjusting the spacing between each reflecting grating) of reflecting grating, number of signals and the signal time missionary society of the inverse signal obtained change, thus can form different codings.When spacing between each reflecting grating that the reflecting grating quantity arranging each surface acoustic wave sensor 220 is different and/or arrange each surface acoustic wave sensor 220 is different, temperature control equipment 210, by resolving coding, just may correspond to and identifies each surface acoustic wave sensor.

In application scenes, surface acoustic wave sensor can be pasted onto on user's body or be arranged on the portable electric appts of user, to gather the temperature around user.

In some implementations, the humidity control system of the present embodiment can also comprise wearable electronic 240.

Wearable electronic 240 can obtain user health data and send to temperature control equipment 210 based on user health data genaration target temperature signal.

It should be noted that, in some implementations, target temperature signal by wearable electronic 240 based on user health data genaration, and can be sent to temperature control equipment 210 by wearable electronic 240 by target temperature signal; Or in other implementations, user health data directly can be sent to temperature control equipment 210 by wearable electronic 240, generate target temperature signal by the temperature controller 212 in temperature control equipment 210 based on user health data.

In some implementations, temperature-adjusting device 230 can comprise blower fan 231 and/or wind deflector 232.Temperature-adjusting device 230 can regulate the air output of blower fan 231 and/or the direction of wind deflector 232 based on the temperature control signals exported based on temperature control equipment 210.

In some implementations, temperature control equipment 210 and temperature-adjusting device 230 can be set to two independently devices, can data interaction be carried out therebetween.Or, in other implementations, temperature control equipment 210 can be arranged on temperature-adjusting device 230.Or, in other implementations, temperature control equipment 210 can also be integrated on temperature-adjusting device 230, make temperature control equipment 210 as the submodule of in temperature-adjusting device 230.

Going out as shown in Figure 4, is the schematic diagram 400 of a kind of application scenarios of the humidity control system according to the application's embodiment.

In this application scenarios, humidity control system comprises temperature control equipment 410, temperature-adjusting device 420 and five passive temperature sensors 401 ~ 405.Wherein, temperature-adjusting device 420 can the wind in outbound course A ~ direction I totally nine directions.

Temperature control equipment 410 sends radiofrequency signal to each passive temperature sensor 401 ~ 405, and receives passive temperature sensor 401 ~ 405 and return current temperature signal and id signal.

When temperature-adjusting device 420 wind direction is A, passive temperature sensor 401 returns temperature value 401A, when wind direction is B, returns temperature value 401B.By that analogy, the temperature value of the passive temperature sensor 401 that wind direction A ~ I is corresponding is 401A ~ 401I.When wind direction is in A or B position, the temperature value of passive temperature sensor 401 is closer to the temperature of temperature-adjusting device 420 air-out.So 401A or 402B is than the temperature of 401C ~ 401I closer to temperature-adjusting device 420 air-out.Thus judge, the position of passive temperature sensor 401 is on A or B direction.Same method, can judge the orientation of passive temperature sensor 402 ~ 405 correspondence.Like this, the coding that returns with each passive temperature sensor 401 ~ 405 and temperature signal is turned to can to judge the orientation of each passive temperature sensor 401 ~ 405 according to temperature-adjusting device 420.

When detecting that the temperature of passive temperature sensor meets setting value, do not change the current setting of temperature-adjusting device 420.When detecting that the temperature of passive temperature sensor 401 ~ 405 does not meet setting value, such as detect that the temperature of passive temperature sensor 401 is higher than design temperature, so can regulate temperature-adjusting device 420, when turning to 1 or 2 position, the time of staying increases, or wind speed improves when temperature-adjusting device 420 turns to 1 or 2 position, or temperature reduces when turning to 1 or 2 position, thus reduce the temperature at sensor 401 place.Like this, the difference of the temperature that can return according to passive temperature sensor 401 ~ 405 and target temperature adjustment temperature control signals, and then adjustment temperature-adjusting device 42 exports wind direction, wind speed and/or output temperature etc. and realizes automatic temperature and regulate.

In application scenarios as shown in Figure 4, the temperature adjustment process of humidity control system can schematically represent by flow chart 500 as shown in Figure 5.

Specifically, in step 510, passive temperature sensor carries out temperature sensing.Then, in step 520, the identification information that returns of the wind direction that exports according to temperature-adjusting device of temperature control equipment and passive temperature sensor and temperature information judge the orientation of passive temperature sensor.Then, in step 530, judge whether the Current Temperatures that each passive temperature sensor senses mates with target temperature.If coupling, then return step 510, passive temperature sensor proceeds temperature sensing.If the Current Temperatures that there is passive temperature sensor sensing does not mate with target temperature, then in step 540, the Current Temperatures sensed based on this passive temperature sensor and the difference of target temperature adjust the temperature control signals that temperature control equipment exports, and in step 550, the wind direction that the temperature control signals correspondence adjustment temperature-adjusting device exported according to temperature control equipment exports, at least one in wind speed output temperature.

When embody rule, step 510 ~ step 550 as above intermittently can perform with predetermined time interval, or, also can carry out temperature sensing, the judgement of passive temperature sensor orientation, the adjustment of temperature control signals and the adjustment of temperature-adjusting device output in real time.

As shown in Figure 6, be the indicative flowchart of the temperature-controlled process of the embodiment of the present application.

Specifically, in step 610, activation signal is sent to passive temperature sensor.

In step 620, the inverse signal of the passive temperature sensor transmission be activated is received.

In act 630, temperature control signals is generated based on the temperature information in inverse signal and sensor orientation information.

In some implementations, the executive agent of step 610 ~ 630 as above can be such as temperature control equipment.

In some implementations, the generating temperature control signals based on the temperature information in inverse signal and sensor orientation information and can further include of step 630: the Current Temperatures information gathered based on each passive temperature sensor and the corresponding relation determination sensor orientation information of thermostatic output wind direction.

In other implementations, can further include based on the temperature information in inverse signal and sensor orientation information generation temperature control signals of step 630: based on sensor orientation information and the target temperature information corresponding with passive temperature sensor of passive temperature sensor, generate temperature control signals.

Flow chart in accompanying drawing and block diagram, illustrate according to the architectural framework in the cards of the system of various embodiments of the invention, method and computer program product, function and operation.In this, each square frame in flow chart or block diagram can represent a part for module, program segment or a code, and a part for described module, program segment or code comprises one or more executable instruction for realizing the logic function specified.Also it should be noted that at some as in the realization of replacing, the function marked in square frame also can be different from occurring in sequence of marking in accompanying drawing.Such as, in fact the square frame that two adjoining lands represent can perform substantially concurrently, and they also can perform by contrary order sometimes, and this determines according to involved function.Also it should be noted that, the combination of the square frame in each square frame in block diagram and/or flow chart and block diagram and/or flow chart, can realize by the special hardware based system of the function put rules into practice or operation, or can realize with the combination of specialized hardware and computer instruction.

More than describe and be only the preferred embodiment of the application and the explanation to institute's application technology principle.Those skilled in the art are to be understood that, invention scope involved in the application, be not limited to the technical scheme of the particular combination of above-mentioned technical characteristic, also should be encompassed in when not departing from described inventive concept simultaneously, be undertaken being combined by above-mentioned technical characteristic or its equivalent feature and other technical scheme of being formed.The technical characteristic that such as, disclosed in above-mentioned feature and the application (but being not limited to) has similar functions is replaced mutually and the technical scheme formed.

Claims (16)

1. a temperature control equipment, is characterized in that, comprises wireless signal transceiver and controller;

Wherein:

Described wireless signal transceiver sends activation signal to passive temperature sensor, receives the inverse signal of the passive temperature sensor transmission be activated, and inverse signal is sent to described controller;

Described controller generates temperature control signals based on described inverse signal.

2. temperature control equipment according to claim 1, is characterized in that:

Described controller resolves described inverse signal with the temperature information of the identification information and sensing that obtain passive temperature sensor;

Described controller generates temperature control signals based on the temperature information of described sensing and target temperature information.

3. temperature control equipment according to claim 1 and 2, is characterized in that:

Described controller also obtains thermostatic wind direction information, and the corresponding relation based on the temperature information of wind direction and described sensing judges the orientation of described passive temperature sensor.

4. temperature control equipment according to claim 2, is characterized in that:

When the distance of described controller between multiple described passive temperature sensor is greater than predetermined threshold, the temperature information of the sensing of each described passive temperature sensor of resolving based on described controller generates the temperature control signals corresponding to this passive temperature sensing station.

5. temperature control equipment according to claim 2, is characterized in that:

Described controller is when the spacing of multiple described passive temperature sensor is less than predetermined threshold, the temperature information determination temperature averages of the sensing of each described passive temperature sensor of resolving based on described controller, and based on the temperature control signals in described temperature averages determination predetermined threshold range.

6. temperature control equipment according to claim 2, is characterized in that, described target temperature information is determined based on following at least one item:

User health situation, history target temperature data and indoor and outdoor temperature are poor.

7. a humidity control system, is characterized in that, comprises at least one passive temperature sensor, temperature control equipment and temperature-adjusting device;

Wherein:

Described passive temperature sensor gathers Current Temperatures information and is sent to described temperature control equipment;

Described temperature control equipment generates temperature control signals based on Current Temperatures information and described temperature control signals is sent to described temperature-adjusting device;

Described temperature-adjusting device carries out temperature adjustment based on temperature control signals.

8. humidity control system according to claim 7, is characterized in that:

Described passive temperature sensor receives the activation signal that described temperature control equipment sends, and generates corresponding inverse signal and send to described temperature control equipment.

9. humidity control system according to claim 7, is characterized in that:

Described passive temperature sensor comprises surface acoustic wave sensor.

10. humidity control system according to claim 9, is characterized in that:

Described humidity control system comprises the surface acoustic wave sensor of more than two, and the reflecting grating quantity of each described surface acoustic wave sensor is all not identical.

11. humidity control systems according to claim 9, is characterized in that:

Described humidity control system comprises the surface acoustic wave sensor of more than two, and spacing distance between the reflecting grating of each described surface acoustic wave sensor is all not identical.

12. humidity control systems according to claim 7-11 any one, is characterized in that:

Also comprise wearable electronic, for obtaining user health data and sending to temperature control equipment based on user health data genaration target temperature signal.

13. humidity control systems according to claim 7-11 any one, is characterized in that:

Described temperature-adjusting device comprises blower fan and/or wind deflector;

Described temperature-adjusting device regulates the direction of the air output of described blower fan and/or described wind deflector based on described temperature control signals.

14. 1 kinds of temperature-controlled process, is characterized in that, comprising:

Activation signal is sent to passive temperature sensor;

Receive the inverse signal of the passive temperature sensor transmission be activated; And

Temperature control signals is generated based on the temperature information in inverse signal and sensor orientation information.

15. temperature-controlled process according to claim 14, is characterized in that, describedly generate temperature control signals based on the temperature information in inverse signal and sensor orientation information and comprise:

Described sensor orientation information is determined based on the Current Temperatures information of each described passive temperature sensor collection and the corresponding relation of thermostatic output wind direction.

16. temperature-controlled process according to claims 14 or 15, is characterized in that, describedly generate temperature control signals based on the temperature information in inverse signal and sensor orientation information and comprise:

Based on sensor orientation information and the target temperature information corresponding with described passive temperature sensor of described passive temperature sensor, generate temperature control signals.