CN109059225A - Using the intelligent temperature control system of the smart home system of mobile network communication - Google Patents

Abstract

The present invention relates to a kind of intelligent temperature control systems of smart home system using mobile network communication, comprising: control host, sensing device and temperature-adjusting device；Sensing device and temperature-adjusting device are connect with control host respectively；Controlling host includes processing module and communication module；Processing module is connect with sensing device and temperature-adjusting device；Communication module is connect with processing module, is used for receiving and transmitting signal；Temperature-adjusting device includes shell, temperature adjustment module, the first probe and heat sink, and temperature adjustment module and the first probe are set in shell, and shell is placed on heat sink；Sensing device includes the second probe and elastic plate, and the second probe is connected to elastic plate.The environmental condition that the present invention passes through acquisition sensing device and temperature adjustment module respectively, error caused by the difference of the environmental condition of local space can be reduced, control host is greatly improved to the precision of temperature adjustment module job control, reduces control host misoperation probability.

Description

Using the intelligent temperature control system of the smart home system of mobile network communication

Technical field

The present invention relates to smart homes, more particularly to the intelligent temperature of the smart home system using mobile network communication Control system.

Background technique

With the continuous improvement of people's living standards, requirement of the people to living conditions is also higher and higher.Smart home from New things in people's eye also progress into ordinary citizen's family, become especially common.Existing smart home is based primarily upon Two aspects realize the intelligent control of household, are on the one hand to use communication module, each household electrical appliances and resident in smart home pass through logical Letter module carries out telecommunication, and user can remotely manipulate household electrical appliances；On the other hand be then using induction module, such as it is infrared Induction, temperature sense, brightness impression or humidity inductive are carried out by incuding the data detected with the preset data that family electrically activates It compares, according to the working condition of the no control household electrical appliances of comparison result.Home wiring control is carried out using first way, accuracy is directed to Property stronger, accuracy of judgement, but need manual operation, resident's perception is not high；Home wiring control is carried out using the second way, although saving It is artificial, but there are still precision at present not high, the big problem of misoperation probability.

Summary of the invention

Based on this, it is necessary to which high for existing smart home system manual intervention degree, control precision is low, misoperation probability Big defect, it is low to provide a kind of manual intervention degree, and control precision is high, the low intelligent temperature control system of misoperation probability.

A kind of intelligent temperature control system, comprising: control host, sensing device and temperature-adjusting device；The induction dress It sets and is connect respectively with the control host with the temperature-adjusting device；

The control host includes processing module and communication module；

The processing module is connect with the sensing device and the temperature-adjusting device, for obtaining the sensing device and institute Thermostatic sensed data is stated, and the temperature-adjusting device is controlled according to the sensed data and is opened or closed；

The communication module is connect with the processing module, is used for receiving and transmitting signal；

The temperature-adjusting device include shell, temperature adjustment module, first probe and heat sink, the temperature adjustment module and First probe is set in the shell, and the shell is placed on the heat sink；

The sensing device includes the second probe and elastic plate, and second probe is connected to the elastic plate.

In one embodiment, the heat sink includes heat-sink shell, heat-conducting layer and heat dissipating layer.

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

In one embodiment, the depth of the groove is set as 2mm-5mm.

In one embodiment, the depth of the groove is set as 3.5mm.

In one embodiment, the heat-sink shell is metal layer.

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

Above-mentioned intelligent temperature control system can by obtaining the environmental condition of sensing device and temperature adjustment module respectively Reduce error caused by the difference of the environmental condition of local space, is greatly improved control host and temperature adjustment module work is controlled The precision of system reduces control host misoperation probability.

Detailed description of the invention

Fig. 1 is the structural block diagram of the intelligent temperature control system of one embodiment of the invention；

Fig. 2 is the structural block diagram of the intelligent temperature control system of another embodiment of the present invention；

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

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

Fig. 5 is the structural block diagram of the sensing device of one embodiment of the invention；

Fig. 6 is the structural block diagram of the sensing device of another embodiment of the present invention.

Specific embodiment

To facilitate the understanding of the present invention, a more comprehensive description of the invention is given in the following sections with reference to the relevant attached drawings.In attached drawing Give better embodiment of the invention.But the invention can be realized in many different forms, however it is not limited to herein Described embodiment.On the contrary, the purpose of providing these embodiments is that making to understand more the disclosure Add thorough and comprehensive.

It should be noted that it can directly on the other element when element is referred to as " being set to " another element Or there may also be elements placed in the middle.When an element is considered as " connection " another element, it, which can be, is directly connected to To another element or it may be simultaneously present centering elements.Term as used herein " vertical ", " horizontal ", " left side ", " right side " and similar statement for illustrative purposes only, are not meant to be the only embodiment.

Unless otherwise defined, all technical and scientific terms used herein and belong to technical field of the invention The normally understood meaning of technical staff is identical.Term as used herein in the specification of the present invention is intended merely to description tool The purpose of the embodiment of body, it is not intended that in the limitation present invention.Term " and or " used herein includes one or more Any and all combinations of relevant listed item.

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

Control host 100, sensing device 300 and temperature-adjusting device 200；The sensing device 300 and the temperature adjust dress 200 are set to connect with the control host 100 respectively.

The control host 100 includes processing module 110 and communication module 120.

The processing module 110 is connect with the sensing device 300, the temperature-adjusting device 200 respectively, for obtaining The sensed data of the sensing device 300 and the temperature-adjusting device 200, and the temperature is controlled according to the sensed data Regulating device 200 opens or closes.

The communication module 120 is connect with the processing module 110, is used for receiving and transmitting signal.

For example, please also refer to Fig. 4, the temperature-adjusting device 200 includes shell 201, temperature adjustment module 210 and the One probe 220, the temperature adjustment module 210 and first probe 220 are set in the shell 201.

The sensing device 300 includes shell 301, second be set in the shell 301 probe 310 and elastic plate 320, second probe 310 is connected to the elastic plate 320.For example, the processing module 110 respectively with the sensing device 300 second probe 310, the temperature adjustment module 210 of the temperature-adjusting device 200 connect.

When work, the control host 100 obtains the sensed data and the induction of the temperature-adjusting device 200 respectively The sensed data of device 300, and by by the sense of the sensed data of the temperature-adjusting device 200 and the sensing device 300 Data are answered to compare, if the sensed data of the temperature-adjusting device 200 and the sensed data of the sensing device 300 Difference is less than preset threshold, then controls the temperature-adjusting device 200 and start, and otherwise, controls the temperature-adjusting device 200 and closes It closes.

As shown in figure 3, a kind of control method of intelligent temperature control system of the present invention are as follows:

Step S100 obtains the sensed data of the first probe, judges whether the sensed data of first probe is greater than default open Dynamic value, is to then follow the steps S200.

Step S200, obtains the sensed data of the second probe, and the sensed data that described second is popped one's head in and described first are visited The sensed data of head compares, and judges the difference of the sensed data of second probe and the sensed data of first probe Whether it is less than preset threshold, is to then follow the steps S300, it is no to then follow the steps S400.

Step S300 controls the temperature adjustment module starting.

Step S400 controls the temperature adjustment module and closes.

Led to by the above method since sensing device 300 and temperature adjustment module 210 install positions different indoors The environmental condition for obtaining sensing device 300 and temperature adjustment module 210 respectively is crossed, the difference of the environmental condition of local space can be reduced Error caused by different is greatly improved control host 100 to the precision of 210 job control of temperature adjustment module, reduces control master 100 misoperation probability of machine.For example, when the sensed data and the sensed data of first probe 220 of second probe 310 When difference is greater than preset threshold, show that there are the inductions that larger difference, i.e., the first probe 220 are got for indoor environmental condition at this time Although data, which are greater than default initiation value, does not constitute starting as caused by this larger difference may be artificial or accident Condition, it is therefore desirable to ignore such case, therefore not start the temperature adjustment module 210；When the induction of second probe 310 When the difference of data and the sensed data of first probe 220 is less than preset threshold, show that indoor environment has general at this time All over property, without significantly floating, therefore, entry condition is constituted.

In order to further increase the control progress of the control host 100, for example, multiple sensing devices 300 are set, it is multiple Sensing device 300 is arranged uniformly around the temperature adjustment module 210, for example, multiple sensing devices 300 and the temperature adjust mould Block 210 is equidistantly positioned；For another example, multiple sensing devices 300 are irregularly arranged in 210 outside of temperature adjustment module.

For example, the second probe 310 by multiple sensing devices 300 gets sensed data respectively；Seek multiple second The mean value of the sensed data of probe 310 is the influence value that is averaged；Judge whether average influence value is greater than default initiation value, is to obtain The sensed data of first probe 220；The sensed data of first probe 220 and the average influence value are compared, sentenced Whether the sensed data of first probe 220 of breaking and the average influence value are less than preset threshold, are to control the temperature Adjustment module 210 starts.

By multiple sensing devices 300 second probe 310 sensed data increase analysis sample, further decrease by The error caused by the difference of the environmental condition of local space further improves the control precision of control host 100.

For another example, sensed data is got by the second probe 310 of multiple sensing devices 300 respectively；It is visited from multiple second Maximum value and minimum value are got in first 310 sensed datas obtained, judges that the difference of the maximum value and the minimum value is It is no be less than preset threshold, be seek it is multiple second probe 310 sensed data mean value i.e. be averaged influence value, judgement averagely feel It should be worth and whether be greater than default initiation value, be the sensed data of the then acquisition first probe 220；By the first probe 220 Sensed data is compared with the average influence value, judges the sensed data and the average induction of first probe 220 Whether value is less than preset threshold, is to control the temperature adjustment module 210 to start.

By comparing the sensed data between multiple sensing devices 300, reduce between sensing device 300 due to local sky Between environmental condition difference caused by error, further improve control host 100 control precision.

For another example, sensed data is got by the second probe 310 of multiple sensing devices 300 respectively；It is visited from multiple second Minimum value is got in first 310 sensed datas obtained, judges whether the minimum value is greater than default initiation value, is, it is described to obtain Take the sensed data of first probe 220；The sensed data of first probe 220 is compared with the minimum value, is judged Whether the sensed data and the minimum value of first probe 220 are less than preset threshold, are to control the temperature to adjust mould Block 210 starts.

The minimum value sensed by obtaining multiple sensing devices 300, in this, as the control temperature adjustment module 210 The foundation of starting improves the sensitivity of control, avoids the startup hysteresis of temperature adjustment module 210 in the variation of environmental condition, makes The control result for controlling host 100 is rapider, more meets resident's demand.

In one embodiment, first probe 220 and second probe 310 are disposed as temperature sense probe.

For example, obtaining the first temperature value of the first probe 220；Judge it is described first probe 220 the first temperature value whether It is the second temperature value for then obtaining the second probe 310 greater than default initiation value；By the second temperature value and first temperature Value compares, and judges whether the second temperature value and the temperature difference of first temperature value are less than fiducial temperature value, is then It controls the temperature adjustment module 210 to start, otherwise, controls the temperature adjustment module 210 and close.

For example, default initiation value is arranged according to the instruction of resident, for example, default initiation value is worked as by the acquisition of control host 100 Date phase is simultaneously arranged according to current date, for example, since summer temperature is higher, the default initiation value setting in summer compared with Height, and winter temperature is lower, then winter corresponding default initiation value setting is lower.

Since temperature-adjusting device 200 can issue a large amount of heat at work, issued to reduce temperature adjustment module 210 Heat to first probe 220 influence, for example, as shown in figure 4, the temperature-adjusting device 200 further includes heat sink 240, institute It states shell 201 to be placed on the heat sink 240, for example, the heat sink 240 includes being sequentially connected heat-sink shell 241, heat-conducting layer 242 and heat dissipating layer 243, the shell 201 be placed on the heat-sink shell 241.

Silica gel is provided in the middle part of the heat-sink shell 241, the shell 201 is connect by silica gel with the heat-sink shell 241.Silicon Glue has good heating conduction, rapidly by the heat absorption of the shell 201 and can be transmitted to the heat-sink shell 241.

In order to improve the heat dissipation performance of heat-sink shell 241, as shown in figure 4,241 surface of the heat-sink shell is provided with multiple grooves 241a, the groove 241a increase the surface area of the heat-sink shell 241, so that heat-sink shell 241 has good heat dissipation performance. For example, the depth of the groove 241a is set as 2mm-5mm, it is preferable that the depth of the groove 241a is set as 3.5mm, answers It should be appreciated that the depth of the groove 241a is unsuitable too deep, and it is too deep, it is easy to cause heat to be gathered in groove 241a and is not easy It distributes, and the depth of the groove 241a should not be excessively shallow, the surface area of heat-sink shell 241 is shallowly then made to increase insufficient, Bu Nengda excessively To the expected purpose for improving heat dissipation effect.

The heat-sink shell 241 is set as metal layer, for example, the heat-sink shell 241 is copper alloy layer.The heat-sink shell 241 Copper alloy include following mass parts each component:

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

Preferably, the heat-sink shell 241 includes each component of following mass parts:

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

There is good heat absorption capacity by the alloy that above-mentioned each component synthesizes, wherein the coefficient of heat conduction of 86 parts of copper is kept In 360W/mK~380W/mK, the temperature of shell 201 can be absorbed rapidly, and there is good corrosion resistance, greatly extend and inhale The service life of thermosphere 241.

In order to improve the heat transfer efficiency of the heat-conducting layer 242, the heat that heat-sink shell 241 is absorbed passes through heat-conducting layer 242 are transmitted to rapidly the heat dissipating layer 243, and the heat-conducting layer 242 is set as aluminium alloy layer, 242 thickness of the heat-conducting layer setting For 8mm-13mm, it is preferable that 242 thickness of heat-conducting layer is set as 10mm, and the thickness setting of heat-conducting layer 242 is particularly critical, leads 242 thickness of thermosphere is blocked up, then the heat for causing heat-sink shell 241 to absorb cannot be transmitted to rapidly heat dissipating layer 243, and heat-conducting layer 242 is thick It spends thin, then the heat of heat-sink shell 241 is made excessively to concentrate on heat dissipating layer 243, and if the not sufficiently large face of heat dissipating layer 243 Product, then can not quickly disperse heat, reduce radiating efficiency instead, and have higher requirements to the heat dissipation area of heat dissipating layer 243.

For example, the heat-conducting layer 242 includes each component of following mass parts in order to improve the heat transfer efficiency of heat-conducting layer 242:

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

Preferably, the heat-conducting layer 242 includes each component of following mass parts:

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

There is good heating conduction by the alloy that above-mentioned each component synthesizes, by 90 parts of aluminium aluminum alloy heats as main component The coefficient of conductivity is maintained at 330W/mK~350W/mK, heat can be transmitted to rapidly low one of temperature by the high one end of temperature rapidly End so that the heat of heat-sink shell 241 can be transferred to rapidly heat dissipating layer 243, and has good corrosion resistance, greatly extends heat absorption The service life of layer 241.

The heat transfer that heat-conducting layer 242 absorbs heat-sink shell 241 to heat dissipating layer 243, heat dissipating layer 243 rapidly dissipates heat Hair, in order to improve the radiating efficiency of heat dissipating layer 243, for example, the heat dissipating layer 243 is set as copper alloy layer, the heat dissipating layer 243 Each component including following mass parts:

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

Preferably, the heat dissipating layer 243 includes each component of following mass parts:

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

There is good heating conduction by the alloy that above-mentioned each component synthesizes, by 94 parts of copper aluminum alloy heats as main component The coefficient of conductivity is maintained at 350W/mK~360W/mK, can rapidly distribute heat, and has good corrosion resistance, greatly extends The service life of heat-sink shell 241.

In order to further increase the heat transference efficiency inside heat dissipating layer 243, for example, referring again to Fig. 4, the heat dissipating layer It is provided with multiple Rubus Tosaefulins 243a in 243, for another example, mercury has been filled in the Rubus Tosaefulins 243a, for example, the heat dissipating layer It is evenly arranged with multiple Rubus Tosaefulins 243a in 243, is provided with mercury in the Rubus Tosaefulins 243a；For example, the Rubus Tosaefulins 243a Diameter is set as 3mm-6mm, it is preferable that the Rubus Tosaefulins 243a diameter is set as 5mm, and the mercury in Rubus Tosaefulins 243a has good Heat sink 240, can be transmitted to rapidly the outer surface of heat sink 240 by good conduction effect from the heat that heat-conducting plate absorbs.

For example, 240 thickness of heat sink is set as 24mm-38mm, it is preferable that 240 thickness of heat sink is set as 32mm, the Rubus Tosaefulins 243a are set as three layers in the heat sink 240, and between every layer of Rubus Tosaefulins 243a between be divided into 5mm further increases the transmitting of 240 internal heat of heat sink.

In order to improve the radiating efficiency of the heat dissipating layer 243, for example, 243 edge of the heat dissipating layer is set as zigzag, saw The heat dissipating layer 243 of tooth form increases heat dissipation area, improves the radiating efficiency of the heat dissipating layer 243；For another example, Fig. 4 is referred to, institute The edge for stating heat dissipating layer 243 is provided with multiple fin 243b, and the fin 243b and the heat dissipating layer 243, which are integrally formed, to be connected； It is arranged for example, the fin 243b is parallel to the heat dissipating layer 243；For another example, the fin 243b is perpendicular to the heat dissipating layer 243 Setting；The fin 243b thickness is set as 1mm-3mm, it is preferable that the fin 243b thickness is set as 2mm, fin 243b The too thick then heat dissipation effect of thickness is bad, and fin 243b thickness is too thin, and be easy bending deformation, be unfavorable for installing, fin 243b into One step improves the radiating efficiency of heat dissipating layer 243.

Due to heat-sink shell 241, the great heat radiation effect of heat-conducting layer 242 and heat dissipating layer 243, so that temperature adjustment module 210 Temperature can keep a certain range at work, and the influence to the first probe 220 is reduced to minimum.

For example, the control host 100 is also connected with foil gauge 330 in order to improve the control precision of control host 100, For example, as shown in figure 5, the foil gauge 330 is set on the elastic plate 320, for example, the foil gauge 330 is set to institute The side of elastic plate 320 is stated, for example, the foil gauge 330 is tightly attached to the side of the elastic plate 320, the foil gauge 330 is used Stress data is obtained in the deformation for incuding the elastic plate 320, and stress data is fed back to the place of the control host 100 Manage module 110, the processing module 110 in the first temperature value for obtaining the induction of the first probe 220 and the second probe 310 and After second temperature value, judged whether to start the temperature adjustment module 210 according to the stress data of foil gauge 330.

Specifically, since foil gauge 330 is metal resistance strain gauge 330, elastic plate 320 generates shape due to expanding with heat and contract with cold Become, and the deformation bring micro-displacement of elastic plate 320 is then converted to voltage output to processing module 110 by foil gauge 330, from And stress data is obtained, for example, presetting multiple stress datas, the corresponding corresponding temperature value of each stress data works as acquisition To stress data the current temperature value of elastic plate 320 can be got according to the deformation situation of elastic plate 320 expanded with heat and contract with cold.

For example, obtaining the stress data of the foil gauge 330, third temperature value, judgement are obtained according to the stress data Whether the third temperature value is greater than default initiation value, is the first temperature value for then obtaining the first probe 220；Obtain the second probe 310 second temperature value；The second temperature value and first temperature value are compared, judge the second temperature value with Whether the temperature difference of first temperature value is less than fiducial temperature value, is to control the temperature adjustment module 210 to start.

By the acquisition elastic plate 320 of foil gauge 330 because of the stress data generated that expands with heat and contract with cold, to get elasticity The temperature value of plate 320, so as to improve the control precision of control host 100；On the other hand, then the sound of control host 100 is improved Answer speed, it should be understood that temperature transmitting is transmitted in solids than transmitting in gas faster, and therefore, elastic plate 320 is due to warm The speed that the deformation that swollen shrinkage generates necessarily gets temperature change than the first probe 220 and the second probe 310 faster, thus may be used See, control host 100 can get temperature change faster, and start the temperature adjustment module 210 at the first time；Simultaneously Reduce the first temperature value obtained according to the first probe 220 to determine whether the step of start-up temperature adjustment module 210, greatly Starting efficiency is improved, only after getting third temperature value according to stress data, judges the first temperature value and second temperature value Difference whether be less than preset temperature difference and start the temperature adjustment module 210, i.e., when the corresponding third temperature of stress data Angle value is more than that after presetting initiation value, only need to compare the difference of the first temperature value and second temperature value without judging the first temperature value With second temperature value specific value, the temperature adjustment module 210 can be started, greatly improved the efficiency.

For example, in order to improve the precision of the stress data of the acquisition of the foil gauge 330, the side of affiliated elastic plate 320 Multiple foil gauges 330 are set, for example, multiple foil gauges 330 are arranged in the side of affiliated elastic plate 320, for example, the elastic plate 320 are provided in round, and the foil gauge 330 is uniformly distributed along the circumference side of the elastic plate 320；For another example, the elastic plate 320 are set as rectangular, and the foil gauge 330 is set to four sides of the rectangular elastic plate 320.

For example, the foil gauge 330 is attached at described as shown in fig. 6, the side of the elastic plate 320 has arc surface On arc surface, in this way, arc surface has bigger stretching or squeezes width when elastic plate 320 generates deformation because expanding with heat and contract with cold Degree, so that the sensitivity of foil gauge 330 is higher.

In order to improve deformation amplitude of the elastic plate 320 because of generation of expanding with heat and contract with cold, the sensitivity of foil gauge 330 is improved, for example, As shown in Figure 5 and Figure 6, the elastic plate 320 has the first elastic layer 321, the second elastic layer 322 and third elastic layer 323, institute It states the first elastic layer 321 and the third elastic layer 323 is provided with plastic layer, second elastic layer 322 is set as metal layer, In first elastic layer 321, second elastic layer 322 and the third elastic layer 323, i.e., the foil gauge 330 overlays The foil gauge 330 is abutted with first elastic layer 321, second elastic layer 322 and the third elastic layer 323, It should be understood that first elastic layer 321 and second elastic layer 322 under the action of expanding with heat and contract with cold, have larger Deformation amplitude, and second elastic layer 322 has since the effect of metal heated swollen shrinkage effect is more unobvious Lesser deformation amplitude, in this way, overlaying in first elastic layer 321, second elastic layer 322 and the third elastic layer 323 foil gauge 330 is then significantly stretched or is squeezed, and with bigger stretching or squeezes amplitude, so that foil gauge 330 Sensitivity it is higher.

For example, the plastic layer includes each component of following mass parts:

12 parts~14 parts of polypropylene, 6 parts~10 parts of polycarbonate, 2 parts~4 parts of polyvinyl chloride, 3 parts of poly- carbonic acid resin~5 parts, second 3 parts~6 parts of 6 parts~8 parts of co-polymer, the polymethacrylates of alkene-vinyl acetate and 2 parts~3 parts of polystyrene.

Preferably, the plastic layer includes each component of following mass parts:

13 parts of polypropylene, 8 parts of polycarbonate, 3 parts of polyvinyl chloride, 4 parts of poly- carbonic acid resin, ethylene-the co-polymer of vinyl acetate 7 parts, 5 parts of polymethacrylates and 2.5 parts of polystyrene.

It is well retractility that plastic layer containing said components, which has, has biggish thermal expansion amplitude when being heated, and is cooled When have biggish shrinkage amplitude so that amplitude of expanding with heat and contract with cold is obvious.

For example, first elastic layer 321 is provided with metal layer, second elastic layer with the third elastic layer 323 322 are set as plastic layer, and the foil gauge 330 is overlayed in first elastic layer 321, second elastic layer 322 and described Third elastic layer 323, first elastic layer 321 and second elastic layer 322 are since metal is under the action of expanding with heat and contract with cold With lesser deformation amplitude, and second elastic layer 322 is since plastics are more obvious by the effect for the effect of expanding with heat and contract with cold, because This is with biggish deformation amplitude, in this way, overlaying in first elastic layer 321, second elastic layer 322 and the third The foil gauge 330 of elastic layer 323 is similarly subjected to significantly stretch or squeeze, same to have bigger stretching or squeeze amplitude, makes The sensitivity for obtaining foil gauge 330 is higher.

In order to further increase the sensitivity of the foil gauge, for example, the elastic plate is arranged two, two elastic plates pair Claim setting, the elastic plate includes the first elastic plate and the second elastic plate, and the foil gauge 330 is adhered to first elastic plate With second elastic plate, in this way, when first elastic plate and second elastic plate are because when expanding with heat and contract with cold that deformation occurs, institute Elastic plate is stated by first elastic plate and the second elastic plate stretching or extruding, and then generates stress data, to improve The sensitivity of the foil gauge；For example, first elastic plate and second elastic plate are set to 6mm-10mm, it is excellent Selection of land, first elastic plate and second elastic plate are set to 8mm.

In order to enable 300 interior temperature distribution of sensing device is uniform, so that the temperature value that the second probe 310 obtains is more smart Really, the shell 301 is set as hemispherical shell 301, and second probe 310 is set to the center of circle of hemispherical shell 301, institute The middle part that elastic plate 320 is provided with the hemispherical shell 301 is stated, in this way, can then reduce the temperature that second probe 310 obtains Angle value and the elastic plate 320 are because of the mistake made between temperature value corresponding to the stress data of the acquisition of foil gauge 330 of expanding with heat and contract with cold Difference.

In order to enable the temperature of the indoor induction of sensing device 300 is with interior more closely, for example, the shell 301 is set It is equipped with through-hole 302, for example, the shell 301 is evenly arranged with multiple through-holes 302, for example, multiple through-holes 302 uniformly divide It is distributed in the hemispherical shell 301, for example, the through-hole 302 is provided in round, 302 diameter of through-hole is set as 4~8mm, 302 diameter of through-hole is set as 6mm.

In one embodiment, 210 specific working mode of temperature adjustment module of the invention further include: when first spy The second temperature value that first 220 the first temperature values obtained or second probe 310 obtain is higher than default high temperature early warning value, described Control host 100 controls the temperature adjustment module 210 and freezes, the first temperature value or institute when 220 acquisition of the first probe The second temperature value for stating the acquisition of the second probe 310 is lower than default low temperature early warning value, then controls the temperature adjustment module 210 and make Heat.

Intelligent temperature control system of the present invention further includes LED light, and the LED light includes lamp holder, lampshade and lamp body, the lamp Seat and lamp holder fasten and internal formation cavity, the lamp body are provided in the cavity, and the lamp body includes multiple groups different colours Lamp group, it is described control host 100 according to it is described first probe 220 and it is described second probe 310 obtain temperature value control not It works with lamp group, for example, the temperature that first probe 220 and second probe 310 that control host 100 is got obtain Value is higher, then controls the lamp group starting of the color of cool tone；First probe 220 and described that control host 100 is got The temperature value that second probe 310 obtains is lower, then the lamp group starting of warm-toned color is controlled, in this way, making indoor environment Resident preferably further improves resident's perception.

For example, the LED light further includes third probe, the third probe is that brightness impression is popped one's head in, the third probe With it is described control host 100 connection, for obtaining present intensity；For example, obtaining present intensity；Judge whether present intensity is big In predetermined luminance, it is to control the LED light to be worked according to day mode, otherwise judges whether present intensity is less than predetermined luminance And the difference of luminance difference round the clock is to control the LED light to be worked according to night mode, otherwise controls the LED light and stops work Make.

It should be understood that predetermined luminance is the average brightness on current season daytime, if present intensity is bright greater than presetting Degree, then show to be currently daytime, and the brightness of daytime to night gradually changes, and the difference of the brightness at daytime and night is bright round the clock Difference is spent, then the brightness at night is that predetermined luminance subtracts luminance difference round the clock；If present intensity is less than the predetermined luminance on daytime, And be greater than predetermined luminance and the round the clock difference of luminance difference, then show to be at this time daytime and alternate period at night, can be multitude Bright or dusk, then control LED light stops working at this time, to save energy consumption.

The precision of the LED light work is controlled to further increase the control host 100 according to present intensity, it is described Sensing device 300 further includes the 4th probe, and the 4th probe is that brightness impression is popped one's head in, and the third probe is led with the control The connection of machine 100, for obtaining present intensity；For example, obtaining the first brightness of the third probe；Judge first brightness Whether it is greater than predetermined luminance, is the second brightness for obtaining the 4th probe, judges second brightness and described first bright Whether the difference of degree is less than predetermined luminance threshold value, is, controls the LED light and is worked according to day mode, otherwise judges described Whether one brightness is less than predetermined luminance and the round the clock difference of luminance difference, is to judge second brightness and first brightness Whether difference is less than predetermined luminance threshold value, is, controls the LED light and is worked according to night mode, otherwise controls the LED light It is standby.

The first brightness popped one's head in by the third and the second brightness of the 4th probe compare, and can reduce part Error caused by the difference of the environmental condition in space greatly improves control host 100 to the precision of LED light job control, reduces Control 100 misoperation probability of host.

For example, the LED light is according to the first temperature value that day mode work is specially when first probe 220 obtains Or the second temperature value that second probe 310 obtains is higher than default high temperature early warning value, then controls the cool tone of the LED light The lamp group of color starts, and after the lamp group of the color of the cool tone of the LED light starts 30 seconds, closes the LED light, works as institute It is pre- that the second temperature value that the first temperature value or second probe 310 for stating the acquisition of the first probe 220 obtain is lower than default low temperature Alert value then controls the lamp group starting of the warm-toned color of the LED light, when the lamp group of the warm-toned color of the LED light After starting 30 seconds, the LED light is closed；The LED light is specially when first probe 220 obtains according to night mode work The second temperature value that the first temperature value or second probe 310 taken obtains is higher than default high temperature early warning value, then described in control The lamp group of the color of the cool tone of LED light starts, when the first temperature value or second probe that first probe 220 obtains The 310 second temperature values obtained are lower than default low temperature early warning value, then the lamp group for controlling the warm-toned color of the LED light opens It is dynamic.

Under day mode, by the starting of LED light, the exception of resident's room temperature at this time is informed, and close institute after starting LED light is stated, achievees the purpose that save energy consumption, and under night mode, then without closing LED light, persistently light the LED light Cool tone lamp group or warm tones lamp group make resident feel more comfortable, improve user's perception.

In one embodiment, described as shown in Fig. 2, intelligent temperature control system of the present invention further includes mobile terminal 400 The communication module 120 for controlling host 100 and the mobile terminal 400 are by being wirelessly connected, for example, the mobile terminal 400 control signal to the control host 100 by wireless transmission, control the temperature adjustment module 210 and work；For example, institute 400 emissioning controling signal of mobile terminal is stated to the control host 100, the control host 100 is according to first mode or second Mode works, and the first mode controls institute according to the control instruction of the mobile terminal 400 for the control host 100 Temperature adjustment module 210 and LED light work are stated, the second mode is the control host 100 according to sensing device 300 The sensed data of induction controls the temperature adjustment module 210 and LED light work.

The communication mode of the communication module 120 includes WIFI and mobile network 2G/3G/4G, in this way, resident can pass through shifting Dynamic terminal 400 remotely controls the control host 100, and receives the anti-of the control host 100 by the mobile terminal 400 Feedback signal, for example, the feedback signal includes the working condition of temperature adjustment module 210 and LED light.

Each technical characteristic of embodiment described above can be combined arbitrarily, for simplicity of description, not to above-mentioned reality It applies all possible combination of each technical characteristic in example to be all described, as long as however, the combination of these technical characteristics is not deposited In contradiction, all should be considered as described in this specification.

The embodiments described above only express several embodiments of the present invention, and the description thereof is more specific and detailed, but simultaneously It cannot therefore be construed as limiting the scope of the patent.It should be pointed out that coming for those of ordinary skill in the art It says, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to protection of the invention Range.Therefore, the scope of protection of the patent of the invention shall be subject to the appended claims.

Claims (7)

1. a kind of intelligent temperature control system characterized by comprising

Control host, sensing device and temperature-adjusting device；The sensing device and the temperature-adjusting device respectively with it is described Control host connection；

The control host includes processing module and communication module；

The processing module is connect with the sensing device and the temperature-adjusting device, for obtaining the sensing device and institute Thermostatic sensed data is stated, and the temperature-adjusting device is controlled according to the sensed data and is opened or closed；

The communication module is connect with the processing module, is used for receiving and transmitting signal；

The temperature-adjusting device include shell, temperature adjustment module, first probe and heat sink, the temperature adjustment module and First probe is set in the shell, and the shell is placed on the heat sink；

The sensing device includes the second probe and elastic plate, and second probe is connected to the elastic plate；

The intelligent temperature control system further includes mobile terminal, and the communication module of the control host and the movement are eventually By being wirelessly connected, the mobile terminal controls signal to the control host by wireless transmission at end, controls the temperature tune Save module work；

The communication mode of the communication module includes WIFI and mobile network；

The working method of the intelligent temperature control system, comprising:

Step S100 obtains the sensed data of the first probe, judges whether the sensed data of first probe is greater than default open Dynamic value, is to then follow the steps S200；

Step S200 obtains the sensed data of the second probe, what the sensed data that described second is popped one's head in and described first were popped one's head in Sensed data compares, judge it is described second probe sensed data and it is described first probe sensed data difference whether It is to then follow the steps S300 less than preset threshold, it is no to then follow the steps S400；

Step S300 controls the temperature adjustment module starting；

Step S400 controls the temperature adjustment module and closes.

2. intelligent temperature control system according to claim 1, which is characterized in that the heat sink includes heat-sink shell, leads Thermosphere and heat dissipating layer.

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

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

5. intelligent temperature control system according to claim 1, which is characterized in that it is described can temperature control system further include LED light, LED light include lamp holder, lampshade and lamp body, and the lamp holder and lamp holder fasten and internal formation cavity, the lamp body include The lamp group of multiple groups different colours controls if the temperature value that first, second probe that control host is got obtains is higher The lamp group of the color of cool tone starts.

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

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