CN105045126A - Intelligent temperature-control system - Google Patents

Abstract

The invention relates to an intelligent temperature-control system comprising an intelligent temperature-control system comprising a control host, an induction device, and a temperature adjustment device. The induction device and the temperature adjustment device are respectively connected with the control host. The control host includes a processing module and a communication module; the processing module is connected with the induction device and the temperature adjustment device; and the communication module connected with the processing module is used for receiving and transmitting signals. The temperature adjustment device consists of a shell, a temperature adjustment module, a first probe and a heat dissipation plate; the temperature adjustment module and the first probe are arranged inside the shell; and the shell is arranged on the heat dissipation plate. The induction device includes a second probe and an elastic plate; and the second probe is abutted against the elastic plate. According to the invention, the environmental conditions of the induction device and the temperature adjustment module are respectively obtained and thus an error caused by the difference of environmental conditions of local space can be reduced; precision of working control of the temperature adjustment module by the control host can be substantially improved; and the misoperation probability of the control host can be reduced.

Description

Intelligent temperature control system

Technical field

The present invention relates to Smart Home, particularly relate to intelligent temperature control system.

Background technology

Along with improving constantly of people's living standard, the requirement of people to living conditions is also more and more higher.Smart Home also progresses into ordinary citizen's family from the new things people's eye, becomes particularly common.Existing Smart Home mainly realizes the Based Intelligent Control of household based on two aspects, be adopt communication module on the one hand, each household electrical appliances in Smart Home and resident family carry out telecommunication by communication module, and user can long-rangely manipulate household electrical appliances; Be then adopt induction module, such as infrared induction, temperature sense, brightness impression or humidity inductive on the other hand, the preset data that the data detected by induction and household electrical appliances are started is compared, according to the duty of the no control household electrical appliances of comparison result.Adopt first kind of way to carry out home wiring control, accuracy, specific aim are comparatively strong, accuracy of judgement, but need manual operation, and resident family's perception is not high; Adopt the second way to carry out home wiring control, although save artificial, still there is precision at present not high, the problem that misoperation probability is large.

Summary of the invention

Based on this, be necessary for existing intelligent domestic system manual intervention degree high, control accuracy is low, the defect that misoperation probability is large, and provide a kind of manual intervention degree low, control accuracy is high, the intelligent temperature control system that misoperation probability is low.

A kind of intelligent temperature control system, comprising: main control system, induction installation and temperature control equipment; Described induction installation is connected with described main control system respectively with described temperature control equipment;

Described main control system comprises processing module and communication module;

Described processing module is connected with described induction installation and described temperature control equipment, for obtaining described induction installation and described thermostatic sensed data, and controls the unlatching of described temperature control equipment according to described sensed data or closes;

Described communication module is connected with described processing module, for receiving and transmitting signal;

Described temperature control equipment comprises shell, temperature adjustment module, the first probe and heat sink, and described temperature adjustment module and described first probe are arranged in described shell, and described shell is placed on described heat sink;

Described induction installation comprises the second probe and elastic plate, and described second probe is connected to described elastic plate.

In one embodiment, described heat sink comprises heat-sink shell, heat-conducting layer and heat dissipating layer.

In one embodiment, described heat-sink shell has groove.

In one embodiment, the degree of depth of described groove is set to 2mm-5mm.

In one embodiment, the degree of depth of described groove is set to 3.5mm.

In one embodiment, described heat-sink shell is metal level.

In one embodiment, described heat-sink shell is copper alloy layer.

Above-mentioned intelligent temperature control system, by obtaining the environmental baseline of induction installation and temperature adjustment module respectively, the error that the difference that can reduce the environmental baseline of local space causes, can improve the precision of main control system to temperature adjustment module job control greatly, reduces main control system misoperation probability.

Accompanying drawing explanation

Fig. 1 is the structured flowchart of the intelligent temperature control system of one embodiment of the invention;

Fig. 2 is the structured flowchart of the intelligent temperature control system of another embodiment of the present invention;

Fig. 3 is the schematic flow sheet of the control method of the intelligent temperature control system of one embodiment of the invention;

Fig. 4 is the thermostatic structural representation of one embodiment of the invention;

Fig. 5 is the structured flowchart of the induction installation of one embodiment of the invention;

Fig. 6 is the structured flowchart of the induction installation of another embodiment of the present invention.

Embodiment

For the ease of understanding the present invention, below with reference to relevant drawings, the present invention is described more fully.Better embodiment of the present invention is given in accompanying drawing.But the present invention can realize in many different forms, is not limited to embodiment described herein.On the contrary, provide the object of these embodiments be make to disclosure of the present invention understand more thorough comprehensively.

It should be noted that, when element is called as " being arranged at " another element, directly can there is element placed in the middle in it on another element or also.When an element is considered to " connection " another element, it can be directly connected to another element or may there is centering elements simultaneously.Term as used herein " vertical ", " level ", "left", "right" and similar statement just for illustrative purposes, do not represent it is unique embodiment.

Unless otherwise defined, all technology used herein and scientific terminology are identical with belonging to the implication that those skilled in the art of the present invention understand usually.The object of term used in the description of the invention herein just in order to describe concrete embodiment, is not intended to be restriction the present invention.Term as used herein " and/or " comprise arbitrary and all combinations of one or more relevant Listed Items.

As shown in Figure 1, it is the intelligent temperature control system of a preferred embodiment of the present invention, comprising:

Main control system 100, induction installation 300 and temperature control equipment 200; Described induction installation 300 is connected with described main control system 100 respectively with described temperature control equipment 200.

Described main control system 100 comprises processing module 110 and communication module 120.

Described processing module 110 is connected with described induction installation 300, described temperature control equipment 200 respectively, for obtaining the sensed data of described induction installation 300 and described temperature control equipment 200, and control described temperature control equipment 200 according to described sensed data and open or close.

Described communication module 120 is connected, for receiving and transmitting signal with described processing module 110.

Such as, please also refer to Fig. 4, described temperature control equipment 200 comprises shell 201, temperature adjustment module 210 and the first probe 220, and described temperature adjustment module 210 and described first probe 220 are arranged in described shell 201.

Described induction installation 300 comprises housing 301, the second probe 310 and the elastic plate 320 be arranged in described housing 301, and described second probe 310 is connected to described elastic plate 320.Such as, described processing module 110 pops one's head in 310 respectively with described second of described induction installation 300, the temperature adjustment module 210 of described temperature control equipment 200 is connected.

During work, described main control system 100 obtains the sensed data of described temperature control equipment 200 and the sensed data of described induction installation 300 respectively, and by the sensed data of described temperature control equipment 200 and the sensed data of described induction installation 300 are contrasted, if the difference of the sensed data of described temperature control equipment 200 and the sensed data of described induction installation 300 is less than predetermined threshold value, then control described temperature control equipment 200 to start, otherwise, control described temperature control equipment 200 and close.

As shown in Figure 3, the control method of a kind of intelligent temperature control system of the present invention is:

Step S100, obtains the sensed data of the first probe, judges whether the sensed data of described first probe is greater than default initiation value, is perform step S200.

Step S200, obtain the sensed data of the second probe, the sensed data of described second probe and the described first sensed data of popping one's head in are contrasted, judge whether the described sensed data of the second probe and the difference of the described first sensed data of popping one's head in are less than predetermined threshold value, be perform step S300, otherwise perform step S400.

Step S300, controls described temperature adjustment module and starts.

Step S400, controls described temperature adjustment module and closes.

Pass through said method, because induction installation 300 and temperature adjustment module 210 are arranged on indoor different position, by obtaining the environmental baseline of induction installation 300 and temperature adjustment module 210 respectively, the error that the difference that can reduce the environmental baseline of local space causes, greatly can improve the precision of main control system 100 pairs of temperature adjustment module 210 job controls, reduce main control system 100 misoperation probability.Such as, when the sensed data and described first of described second probe 310 pop one's head in 220 the difference of sensed data be greater than predetermined threshold value time, show that now indoor environmental condition exists larger difference, although the sensed data that namely the first probe 220 gets is greater than default initiation value, but because this larger difference may artificial or accident cause, do not form entry condition, therefore need to ignore this situation, therefore do not start described temperature adjustment module 210; When the sensed data and described first of described second probe 310 pop one's head in 220 the difference of sensed data be less than predetermined threshold value time, show that now indoor environment has ubiquity, nothing is significantly floated, therefore, formation entry condition.

In order to improve the control progress of described main control system 100 further, such as, arrange multiple induction installation 300, multiple induction installation 300 is evenly arranged around described temperature adjustment module 210, such as, multiple induction installation 300 and the equidistant setting of described temperature adjustment module 210; And for example, multiple induction installation 300 is irregular is arranged on outside described temperature adjustment module 210.

Such as, sensed data is got respectively by the second probe 310 of multiple induction installation 300; Ask for the average of the sensed data of multiple second probe 310 and average influence value; Judge whether average influence value is greater than default initiation value, is, obtain the sensed data of described first probe 220; The sensed data of the first probe 220 and described average influence value are contrasted, judges whether the sensed data of described first probe 220 and described average influence value are less than predetermined threshold value, are control described temperature adjustment module 210 and start.

Add analyzing samples by the sensed data of the second probe 310 of multiple induction installation 300, reduce the error because the difference of the environmental baseline of local space causes further, further increase the control accuracy of main control system 100.

And for example, sensed data is got respectively by the second probe 310 of multiple induction installation 300; Maximal value and minimum value is got from the sensed data that multiple second probe 310 obtains, judge whether the difference of described maximal value and described minimum value is less than predetermined threshold value, ask for the average of the sensed data of multiple second probe 310 and average influence value, judging whether average influence value is greater than default initiation value, is the sensed data of described first probe 220 of then described acquisition; The sensed data of the first probe 220 and described average influence value are contrasted, judges whether the sensed data of described first probe 220 and described average influence value are less than predetermined threshold value, are control described temperature adjustment module 210 and start.

By contrasting the sensed data between multiple induction installation 300, due to the error that the difference of the environmental baseline of local space causes between reduction induction installation 300, further increase the control accuracy of main control system 100.

And for example, sensed data is got respectively by the second probe 310 of multiple induction installation 300; From the sensed data that multiple second probe 310 obtains, getting minimum value, judge whether described minimum value is greater than default initiation value, is the sensed data of described first probe 220 of then described acquisition; The sensed data of the first probe 220 and described minimum value are contrasted, judges whether the sensed data of described first probe 220 and described minimum value are less than predetermined threshold value, are control described temperature adjustment module 210 and start.

By obtaining the minimum value that multiple induction installation 300 senses, in this, as the foundation controlling the startup of described temperature adjustment module 210, improve the sensitivity controlled, avoid the change of startup hysteresis in environmental baseline of temperature adjustment module 210, make the control result of main control system 100 rapider, more meet resident family's demand.

In one embodiment, described first probe 220 and described second probe 310 are all set to temperature sense probe.

Such as, the first temperature value of the first probe 220 is obtained; Judge whether the first temperature value of described first probe 220 is greater than default initiation value, is obtain the second temperature value of the second probe 310; Described second temperature value and described first temperature value are contrasted, judge whether the temperature approach of described second temperature value and described first temperature value is less than default temperature approach, control described temperature adjustment module 210 and start, otherwise, control described temperature adjustment module 210 and close.

Such as, preset initiation value to arrange according to the instruction of resident family, such as, preset initiation value obtain the current date by main control system 100 and arrange according to current date, such as, because summer temperature is higher, therefore the default initiation value in summer arrange higher, and winter temperature is lower, then it is lower that the default initiation value that winter is corresponding is arranged.

Because temperature control equipment 200 operationally can send a large amount of heat, in order to reduce heat that temperature adjustment module 210 sends to the impact of the first probe 220, such as, as shown in Figure 4, described temperature control equipment 200 also comprises heat sink 240, and described shell 201 is placed on described heat sink 240, such as, described heat sink 240 comprises and connects heat-sink shell 241, heat-conducting layer 242 and heat dissipating layer 243 successively, and described shell 201 is placed on described heat-sink shell 241.

Be provided with silica gel in the middle part of described heat-sink shell 241, described shell 201 is connected with described heat-sink shell 241 by silica gel.Silica gel has good heat conductivility, rapidly the heat absorption of described shell 201 can be delivered to described heat-sink shell 241.

In order to improve the heat dispersion of heat-sink shell 241, as shown in Figure 4, described heat-sink shell 241 surface is provided with multiple groove 241a, and described groove 241a adds the surface area of described heat-sink shell 241, makes heat-sink shell 241 have good heat dispersion.Such as, the degree of depth of described groove 241a is set to 2mm-5mm, preferably, the degree of depth of described groove 241a is set to 3.5mm, it should be understood that the degree of depth of described groove 241a should not be excessively dark, cross and deeply then easily cause heat accumulation not easily to distribute in groove 241a, and the degree of depth of described groove 241a should not be excessively shallow, cross shallow, the surface area of heat-sink shell 241 is increased not enough, the object of the raising radiating effect of expection can not be reached.

Described heat-sink shell 241 is set to metal level, and such as, described heat-sink shell 241 is copper alloy layer.The aldary of described heat-sink shell 241 comprises each component of following mass parts:

Copper 80 parts ~ 92 parts, 6 parts ~ 8 parts, aluminium, iron 0.3 part ~ 0.5 part, 1 part ~ 2.5 parts, magnesium, 0.8 part ~ 1.2 parts, zinc, 0.1 part ~ 0.2 part, manganese, chromium 0.2 part ~ 0.3 part, 2.5 parts ~ 4.5 parts, sodium, vanadium 0.6 part ~ 0.8 part, silicon 1.0 parts ~ 1.2 parts and 0.5 part ~ 2 parts, antimony.

Preferably, described heat-sink shell 241 comprises each component of following mass parts:

Copper 86 parts, 7 parts, aluminium, iron 0.4 part, 1.5 parts, magnesium, 0.9 part, zinc, 0.15 part, manganese, chromium 0.25 part, 3 parts, sodium, vanadium 0.7 part, silicon 1.1 parts and 0.9 part, antimony.

The alloy synthesized by above-mentioned each component has good heat absorption capacity, wherein the heat-conduction coefficient of copper of 86 parts remains on 360W/mK ~ 380W/mK, rapidly by the temperature absorption of shell 201, and good corrosion resistance can be had, greatly extend the serviceable life of heat-sink shell 241.

In order to improve the heat transfer efficiency of described heat-conducting layer 242, the heat that heat-sink shell 241 is absorbed can be delivered to rapidly described heat dissipating layer 243 by heat-conducting layer 242, described heat-conducting layer 242 is set to aluminium alloy layer, described heat-conducting layer 242 thickness is set to 8mm-13mm, preferably, described heat-conducting layer 242 thickness is set to 10mm, the thickness of heat-conducting layer 242 arranges particularly crucial, heat-conducting layer 242 thickness is blocked up, the heat then causing heat-sink shell 241 to absorb can not be delivered to rapidly heat dissipating layer 243, heat-conducting layer 242 thickness is excessively thin, the heat of heat-sink shell 241 is then made too to concentrate on heat dissipating layer 243, if and heat dissipating layer 243 does not have enough large area, then heat cannot be left fast, reduce radiating efficiency on the contrary, and the area of dissipation of heat dissipating layer 243 is had higher requirements.

Such as, in order to improve the heat transfer efficiency of heat-conducting layer 242, described heat-conducting layer 242 comprises each component of following mass parts:

88 parts ~ 96 parts, aluminium, copper 3 parts ~ 6 parts, iron 0.2 part ~ 0.6 part, 1 part ~ 2.5 parts, magnesium, 0.8 part ~ 1.2 parts, zinc, 0.1 part ~ 0.2 part, manganese, 0.4 part ~ 0.6 part, nickel, 1.8 parts ~ 2.4 parts, sodium, vanadium 0.4 part ~ 0.8 part, silicon 1.0 parts ~ 1.2 parts and 0.5 part ~ 2 parts, antimony.

Preferably, described heat-conducting layer 242 comprises each component of following mass parts:

90 parts, aluminium, copper 5 parts, iron 0.4 part, 1.5 parts, magnesium, 0.9 part, zinc, 0.15 part, manganese, 0.5 part, nickel, 2.0 parts, sodium, vanadium 0.6 part, silicon 1.1 parts and 0.8 part, antimony.

The alloy synthesized by above-mentioned each component has good heat conductivility, the aluminum alloy heat transmissibility factor being principal ingredient by 90 parts of aluminium remains on 330W/mK ~ 350W/mK, rapidly heat can be delivered to rapidly the low one end of temperature by one end that temperature is high, make the heat of heat-sink shell 241 can be passed to rapidly heat dissipating layer 243, and there is good corrosion resistance, greatly extend the serviceable life of heat-sink shell 241.

The heat that heat-sink shell 241 absorbs is passed to heat dissipating layer 243 by heat-conducting layer 242, heat distributes rapidly by heat dissipating layer 243, in order to improve the radiating efficiency of heat dissipating layer 243, such as, described heat dissipating layer 243 is set to copper alloy layer, and described heat dissipating layer 243 comprises each component of following mass parts:

Copper 92 parts ~ 96 parts, 4 parts ~ 6 parts, aluminium, iron 0.5 part ~ 0.8 part, 1 part ~ 2.5 parts, magnesium, 0.8 part ~ 1.2 parts, zinc, 0.1 part ~ 0.2 part, manganese, chromium 0.2 part ~ 0.3 part, 2.5 parts ~ 4.5 parts, sodium, vanadium 0.6 part ~ 0.8 part, silicon 1.0 parts ~ 1.2 parts and 0.5 part ~ 2 parts, antimony.

Preferably, described heat dissipating layer 243 comprises each component of following mass parts:

Copper 94 parts, 5 parts, aluminium, iron 0.65 part, 1.5 parts, magnesium, 0.9 part, zinc, 0.15 part, manganese, chromium 0.25 part, 3 parts, sodium, vanadium 0.7 part, silicon 1.1 parts and 0.9 part, antimony.

The alloy synthesized by above-mentioned each component has good heat conductivility, the aluminum alloy heat transmissibility factor being principal ingredient by 94 parts of copper remains on 350W/mK ~ 360W/mK, rapidly heat can be distributed, and there is good corrosion resistance, greatly extend the serviceable life of heat-sink shell 241.

In order to improve the heat transference efficiency of heat dissipating layer 243 inside further, such as, referring again to Fig. 4, multiple Rubus Tosaefulins 243a is provided with in described heat dissipating layer 243, and for example, mercury has been filled with in described Rubus Tosaefulins 243a, such as, evenly be provided with multiple Rubus Tosaefulins 243a in described heat dissipating layer 243, in described Rubus Tosaefulins 243a, be provided with mercury; Such as, described Rubus Tosaefulins 243a diameter is set to 3mm-6mm, and preferably, described Rubus Tosaefulins 243a diameter is set to 5mm, mercury in Rubus Tosaefulins 243a has good conduction effect, heat sink 240 can be delivered to rapidly the outside surface of heat sink 240 from the heat that heat-conducting plate absorbs.

Such as, described heat sink 240 thickness is set to 24mm-38mm, preferably, described heat sink 240 thickness is set to 32mm, described Rubus Tosaefulins 243a is set to three layers in described heat sink 240, and be spaced apart 5mm between every layer of Rubus Tosaefulins 243a, improve the transmission of heat sink 240 internal heat further.

In order to improve the radiating efficiency of described heat dissipating layer 243, such as, described heat dissipating layer 243 edge is set to serrate, and zigzag heat dissipating layer 243 adds area of dissipation, improves the radiating efficiency of described heat dissipating layer 243; And for example, refer to Fig. 4, the edge of described heat dissipating layer 243 is provided with multiple fin 243b, and described fin 243b is connected with described heat dissipating layer 243 is one-body molded; Such as, described fin 243b is parallel to described heat dissipating layer 243 and arranges; And for example, described fin 243b is arranged perpendicular to described heat dissipating layer 243; Described fin 243b thickness is set to 1mm-3mm, and preferably, described fin 243b thickness is set to 2mm, the too thick then radiating effect of fin 243b thickness is not good, and fin 243b thickness is too thin, and easily bending distortion, be unfavorable for installing, fin 243b further increases the radiating efficiency of heat dissipating layer 243.

Due to the great heat radiation effect of heat-sink shell 241, heat-conducting layer 242 and heat dissipating layer 243, make temperature adjustment module 210 operationally temperature can keep certain limit, and on first probe 220 impact be reduced to minimum.

Such as, in order to improve the control accuracy of main control system 100, described main control system 100 is also connected with foil gauge 330, such as, as shown in Figure 5, described foil gauge 330 is arranged on described elastic plate 320, such as, described foil gauge 330 is arranged at the side of described elastic plate 320, such as, described foil gauge 330 is close to the side of described elastic plate 320, described foil gauge 330 obtains stress data for responding to the deformation of described elastic plate 320, and stress data is fed back to the processing module 110 of described main control system 100, described processing module 110 is after the first temperature value of induction obtaining the first probe 220 and the second probe 310 and the second temperature value, judge whether to start described temperature adjustment module 210 according to the stress data of foil gauge 330.

Specifically, because foil gauge 330 is metal resistance strain gauge 330, elastic plate 320 is due to generation deformation of expanding with heat and contract with cold, the micro-displacement that the deformation of elastic plate 320 brings then is converted to voltage and exports processing module 110 to by foil gauge 330, thus obtain stress data, such as, preset multiple stress data, the corresponding corresponding temperature value of each stress data, can get the current temperature value of elastic plate 320 according to the deformation situation of expanding with heat and contract with cold of elastic plate 320 when getting stress data.

Such as, obtain the stress data of described foil gauge 330, obtain the 3rd temperature value according to described stress data, judge whether described 3rd temperature value is greater than default initiation value, is, obtains the first temperature value of the first probe 220; Obtain the second temperature value of the second probe 310; Described second temperature value and described first temperature value are contrasted, judges whether the temperature approach of described second temperature value and described first temperature value is less than default temperature approach, is, control described temperature adjustment module 210 and start.

Obtained the stress data produced because expanding with heat and contract with cold of elastic plate 320 by foil gauge 330, thus get the temperature value of elastic plate 320, improve the control accuracy of main control system 100 with this, on the other hand, then improve the response speed of main control system 100, it should be understood that, temperature transmission is transmitted faster than transmitting in gas in solids, therefore, the deformation that elastic plate 320 produces owing to expanding with heat and contract with cold must get the speed of temperature variation sooner than the first probe 220 and the second probe 310, as can be seen here, main control system 100 can get temperature variation faster, and starts described temperature adjustment module 210 in the very first time, decrease the step that the first temperature value obtained according to the first probe 220 judges whether start-up temperature adjustment module 210 simultaneously, greatly improve starting efficiency, only after get the 3rd temperature value according to stress data, judge whether the difference of the first temperature value and the second temperature value is less than preset temperature difference and namely starts described temperature adjustment module 210, namely after the 3rd temperature value that stress data is corresponding exceedes default initiation value, only need compare the first temperature value and the second temperature value difference and without the need to judging the first temperature value and the concrete numerical value of the second temperature value, described temperature adjustment module 210 can be started, substantially increase efficiency.

Such as, in order to improve the precision of the stress data of the acquisition of described foil gauge 330, the side of affiliated elastic plate 320 arranges multiple foil gauge 330, such as, the side of affiliated elastic plate 320 arranges multiple foil gauge 330, such as, described elastic plate 320 is set to circle, and described foil gauge 330 is uniformly distributed along the circumference side of described elastic plate 320; And for example, described elastic plate 320 is set to square, and described foil gauge 330 is arranged at four sides of described square elastic plate 320.

Such as, as shown in Figure 6, the side of described elastic plate 320 has arc surface, described foil gauge 330 is attached on described arc surface, like this, when elastic plate 320 produces deformation because expanding with heat and contract with cold, arc surface has larger stretching or extruding amplitude, makes the sensitivity of foil gauge 330 higher.

In order to improve elastic plate 320 because of the deformation amplitude produced of expanding with heat and contract with cold, improve the sensitivity of foil gauge 330, such as, as shown in Figure 5 and Figure 6, described elastic plate 320 has the first elastic layer 321, second elastic layer 322 and the 3rd elastic layer 323, described first elastic layer 321 is provided with plastic layer with described 3rd elastic layer 323, described second elastic layer 322 is set to metal level, described foil gauge 330 overlays in described first elastic layer 321, described second elastic layer 322 and described 3rd elastic layer 323, i.e. described foil gauge 330 and described first elastic layer 321, described second elastic layer 322 and described 3rd elastic layer 323 all abut, it should be understood that, described first elastic layer 321 and described second elastic layer 322 are under the effect of expanding with heat and contract with cold, there is larger deformation amplitude, and described second elastic layer 322 due to the effect of metal heated swollen shrinkage effect comparatively not obvious, therefore there is less deformation amplitude, like this, overlay in described first elastic layer 321, the foil gauge 330 of described second elastic layer 322 and described 3rd elastic layer 323 is subject to significantly stretching or extruding, and there is larger stretching or extruding amplitude, make the sensitivity of foil gauge 330 higher.

Such as, described plastic layer comprises each component of following mass parts:

Polypropylene 12 parts ~ 14 parts, polycarbonate 6 parts ~ 10 parts, Polyvinylchloride 2 parts ~ 4 parts, poly-carbonic acid resin 3 parts ~ 5 parts, ethene-the co-polymer 6 parts ~ 8 parts of vinyl acetate, polymethacrylate 3 parts ~ 6 parts and polystyrene 2 parts ~ 3 parts.

Preferably, described plastic layer comprises each component of following mass parts:

Polypropylene 13 parts, polycarbonate 8 parts, Polyvinylchloride 3 parts, poly-carbonic acid resin 4 parts, ethene-the co-polymer 7 parts of vinyl acetate, polymethacrylate 5 parts and polystyrene 2.5 parts.

It is well retractility that plastic layer containing said components has, and has larger hot amount of increase degree, and has larger shrinkage amplitude when catching a cold, make the amplitude of expanding with heat and contract with cold obvious when being heated.

Such as, described first elastic layer 321 is provided with metal level with described 3rd elastic layer 323, described second elastic layer 322 is set to plastic layer, described foil gauge 330 overlays in described first elastic layer 321, described second elastic layer 322 and described 3rd elastic layer 323, described first elastic layer 321 and described second elastic layer 322 have less deformation amplitude due to metal under the effect of expanding with heat and contract with cold, and the effect that described second elastic layer 322 acts on by expanding with heat and contract with cold due to plastics is comparatively obvious, therefore there is larger deformation amplitude, like this, overlay in described first elastic layer 321, the foil gauge 330 of described second elastic layer 322 and described 3rd elastic layer 323 is subject to significantly stretching or extruding equally, there is larger stretching or extruding amplitude equally, make the sensitivity of foil gauge 330 higher.

In order to improve the sensitivity of described foil gauge further, such as, described elastic plate arranges two, two elastic plates are symmetrical arranged, described elastic plate comprises the first elastic plate and the second elastic plate, described foil gauge 330 adheres to described first elastic plate and described second elastic plate, like this, when there is deformation because expanding with heat and contract with cold in described first elastic plate and described second elastic plate, described elastic plate is stretched or extruding by described first elastic plate and described second elastic plate, and then generation stress data, thus improve the sensitivity of described foil gauge; Such as, described first elastic plate and described second elastic plate be set to 6mm-10mm, preferably, described first elastic plate and described second elastic plate be set to 8mm.

In order to make induction installation 300 interior temperature distribution even, the temperature value that second probe 310 is obtained is more accurate, described housing 301 is set to hemispherical shell 301, described second probe 310 is arranged at the center of circle of hemispherical shell 301, described elastic plate 320 is provided with the middle part of described hemispherical shell 301, like this, then can reduce described second probe 310 obtain temperature values and described elastic plate 320 make foil gauge 330 obtain because expanding with heat and contract with cold the temperature value corresponding to stress data between error.

In order to the temperature and indoor that make indoor induction installation 300 induction are more close, such as, described housing 301 is provided with through hole 302, and such as, described housing 301 is evenly provided with multiple through hole 302, such as, multiple described through hole 302 is uniformly distributed in described hemispherical shell 301, and such as, described through hole 302 is set to circle, described through hole 302 diameter is set to 4 ~ 8mm, and described through hole 302 diameter is set to 6mm.

In one embodiment, temperature adjustment module 210 specific works mode of the present invention also comprises: the first temperature value or described second obtained when described first probe 220 pops one's head in 310 the second temperature values obtained higher than default high temperature early warning value, described main control system 100 controls described temperature adjustment module 210 and freezes, the first temperature value or described second obtained when described first probe 220 pops one's head in 310 the second temperature values obtained lower than default low temperature early warning value, then control described temperature adjustment module 210 and heat.

Intelligent temperature control system of the present invention also comprises LED, described LED comprises lamp socket, lampshade and lamp body, described lamp socket and lamp socket fasten and inner formation cavity, described lamp body is provided with in described cavity, described lamp body comprises the lamp group of many group different colours, the temperature value that described main control system 100 obtains according to described first probe 220 and described second probe 310 controls the work of different lamp group, such as, the temperature value of described first probe 220 that main control system 100 gets and described second probe 310 acquisition is higher, then the lamp group controlling the color of cool tone starts; The temperature value of described first probe 220 that main control system 100 gets and described second probe 310 acquisition is lower, then the lamp group controlling warm-toned color starts, and like this, makes indoor environment resident family preferably, further increases resident family's perception.

Such as, described LED also comprises the 3rd probe, and described 3rd probe is the connection of brightness impression probe, described 3rd probe and described main control system 100, for obtaining present intensity; Such as, present intensity is obtained; Judge whether present intensity is greater than predetermined luminance, control described LED according to day mode work, otherwise judge whether present intensity is less than the difference of predetermined luminance and luminance difference round the clock, is control described LED according to night mode work, otherwise control described LED and quit work.

It should be understood that, predetermined luminance is the mean flow rate on current season daytime, if present intensity is greater than predetermined luminance, then show that current is daytime, and brightness at daytime to night gradually changes, the difference of the brightness at daytime and night is luminance difference round the clock, then the brightness at night is that predetermined luminance deducts luminance difference round the clock; If present intensity is less than the predetermined luminance on daytime, and be greater than the difference of predetermined luminance and luminance difference round the clock, then show to be now the time period that daytime and night replace, can be dawn or dusk, then now control LED quits work, to save energy consumption.

To control the precision of described LED work according to present intensity in order to improve described main control system 100 further, described induction installation 300 also comprises the 4th probe, described 4th probe is the connection of brightness impression probe, described 3rd probe and described main control system 100, for obtaining present intensity; Such as, the first brightness of described 3rd probe is obtained; Judge whether described first brightness is greater than predetermined luminance, obtain the second brightness of described 4th probe, judge whether the difference of described second brightness and described first brightness is less than predetermined luminance threshold value, control described LED according to day mode work, otherwise judge whether described first brightness is less than the difference of predetermined luminance and luminance difference round the clock, judge whether the difference of described second brightness and described first brightness is less than predetermined luminance threshold value, control described LED according to night mode work, otherwise it is standby to control described LED.

First brightness of popping one's head in by the described 3rd and the described 4th second brightness of popping one's head in contrast, the error that the difference that can reduce the environmental baseline of local space causes, greatly improve the precision of main control system 100 pairs of LED job controls, reduce main control system 100 misoperation probability.

Such as, described LED is specially when the first temperature value of described first probe 220 acquisition or the second temperature values of described second probe 310 acquisition are higher than default high temperature early warning value according to day mode work, the lamp group then controlling the color of the cool tone of described LED starts, after the lamp group of the color of the cool tone of described LED starts 30 seconds, close described LED, the first temperature value or described second obtained when described first probe 220 pops one's head in 310 the second temperature values obtained lower than default low temperature early warning value, the lamp group then controlling the warm-toned color of described LED starts, after the lamp group of the warm-toned color of described LED starts 30 seconds, close described LED, described LED is specially when the first temperature value of described first probe 220 acquisition or the second temperature values of described second probe 310 acquisition are higher than default high temperature early warning value according to night mode work, the lamp group then controlling the color of the cool tone of described LED starts, the first temperature value or described second obtained when described first probe 220 pops one's head in 310 the second temperature values obtained lower than default low temperature early warning value, then the lamp group controlling the warm-toned color of described LED starts.

Under day mode, by the startup of LED, inform the exception of resident family's now indoor temperature, and close described LED after starting, reach the object of saving energy consumption, and under night mode, then without the need to closing LED, continue cool tone lamp group or the warm tones lamp group of lighting described LED, make resident family feel more comfortable, improve user awareness.

In one embodiment, as shown in Figure 2, intelligent temperature control system of the present invention also comprises mobile terminal 400, described communication module 120 and the described mobile terminal 400 of described main control system 100 pass through wireless connections, such as, described mobile terminal 400 controls signal to described main control system 100 by wireless transmit, controls described temperature adjustment module 210 and works; Such as, described mobile terminal 400 emissioning controling signal is to described main control system 100, described main control system 100 carries out work according to first mode or the second pattern, described first mode is that described main control system 100 controls described temperature adjustment module 210 and described LED work according to the steering order of described mobile terminal 400, and described second pattern is that described main control system 100 controls described temperature adjustment module 210 and described LED work according to the sensed data that induction installation 300 is responded to.

The communication mode of described communication module 120 comprises WIFI and mobile network 2G/3G/4G, like this, resident family is by main control system 100 described in mobile terminal 400 Long-distance Control, and the feedback signal of described main control system 100 is received by described mobile terminal 400, such as, described feedback signal comprises the duty of temperature adjustment module 210 and LED.

Each technical characteristic of the above embodiment can combine arbitrarily, for making description succinct, the all possible combination of each technical characteristic in above-described embodiment is not all described, but, as long as the combination of these technical characteristics does not exist contradiction, be all considered to be the scope that this instructions is recorded.

The above embodiment only have expressed several embodiment of the present invention, and it describes comparatively concrete and detailed, but can not therefore be construed as limiting the scope of the patent.It should be pointed out that for the person of ordinary skill of the art, without departing from the inventive concept of the premise, can also make some distortion and improvement, these all belong to protection scope of the present invention.Therefore, the protection domain of patent of the present invention should be as the criterion with claims.

Claims (7)

1. an intelligent temperature control system, is characterized in that, comprising:

Main control system, induction installation and temperature control equipment; Described induction installation is connected with described main control system respectively with described temperature control equipment;

Described main control system comprises processing module and communication module;

Described processing module is connected with described induction installation and described temperature control equipment, for obtaining described induction installation and described thermostatic sensed data, and controls the unlatching of described temperature control equipment according to described sensed data or closes;

Described communication module is connected with described processing module, for receiving and transmitting signal;

Described temperature control equipment comprises shell, temperature adjustment module, the first probe and heat sink, and described temperature adjustment module and described first probe are arranged in described shell, and described shell is placed on described heat sink;

Described induction installation comprises the second probe and elastic plate, and described second probe is connected to described elastic plate.

2. intelligent temperature control system according to claim 1, is characterized in that, described heat sink comprises heat-sink shell, heat-conducting layer and heat dissipating layer.

3. intelligent temperature control system according to claim 2, is characterized in that, described heat-sink shell has groove.

4. intelligent temperature control system according to claim 3, is characterized in that, the degree of depth of described groove is set to 2mm-5mm.

5. intelligent temperature control system according to claim 4, is characterized in that, the degree of depth of described groove is set to 3.5mm.

6. intelligent temperature control system according to claim 2, is characterized in that, described heat-sink shell is metal level.

7. intelligent temperature control system according to claim 6, is characterized in that, described heat-sink shell is copper alloy layer.