Detailed Description
Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application.
An air conditioning system of an embodiment of the present application is first described with reference to fig. 1.
As shown in fig. 1, the air conditioning system includes an internal circulation subsystem and a fresh air subsystem, and an air outlet of the fresh air subsystem and an air outlet of the internal circulation subsystem are both communicated with an indoor air supply outlet 33 of the air conditioning system through an air mixing area 45. The air conditioning system may be an air handling all-in-one machine.
The internal circulation subsystem is used for adjusting the temperature of indoor air, and includes a heat exchanger 44, a flow channel for flowing through a heat exchange medium is arranged in the heat exchanger 44, the heat exchanger 44 is used for exchanging heat between the heat exchange medium and the air, the heat exchanger 44 may be a coil heat exchanger, the internal circulation subsystem may include a heat exchange circulation loop, the heat exchanger 44 is one of the heat exchange circulation loops, and when the internal circulation subsystem executes a refrigeration mode, the heat exchanger 44 is used as an evaporator. Of course, in other embodiments, the internal circulation subsystem may also have a heating mode, and the heat exchanger 44 may be used as a condenser when the internal circulation subsystem performs a cooling mode. Other structures such as a compressor, an expansion valve and the like in the heat exchange circulation loop are not described in detail herein.
When the internal circulation subsystem works, the temperature control air valve 11 is opened, the air supply fan 41 works, indoor air is sucked into an air channel of the internal circulation subsystem from the internal circulation air return opening 31, the internal circulation filter device 21 can be arranged at the internal circulation air return opening 31, and the air is filtered through the internal circulation filter device 21. Wherein, the internal circulation filter device 21 can be a filter screen.
The air sucked into the air duct exchanges heat at the heat exchanger 44, for example, when the internal circulation subsystem performs a cooling mode, the heat exchanger 44 serves as an evaporator, the heat-exchanged air flows into the air mixing area 45, and is then sent into the room through the indoor air supply opening 33 under the driving of the air supply fan 41, so that the indoor temperature is adjusted.
The three arrows in fig. 1 show the direction of flow of the air in the internal circulation.
The fresh air subsystem is used for sending fresh air into the room, and the fresh air subsystem comprises a total heat exchanger 43, and the total heat exchanger 43 is used for heat exchange between air and air.
When the fresh air subsystem works, the exhaust fan 42 works, indoor foul air is sucked into a return air duct of the fresh air subsystem from the fresh air return opening 32 and then flows into an air flow channel of the total heat exchanger 43, wherein the fresh air return opening 32 can be provided with a fresh air first filtering device 22, air is filtered by the fresh air first filtering device 22, and the fresh air first filtering device 22 can be a filter screen; when the air supply fan 41 works, outdoor fresh air is sucked into the fresh air duct from the outdoor fresh air inlet 34 and then flows into the other air flow passage of the total heat exchanger 43, wherein the second fresh air filtering device 23 can be arranged at the outdoor fresh air inlet 34, and air is filtered by the second fresh air filtering device 23, wherein the second fresh air filtering device can be a filter screen; the heat exchange between the foul air and the fresh air is performed at the outlet of the total heat exchanger 43, the foul air after heat exchange is exhausted to the outside through the outdoor air outlet 35 under the driving of the air exhaust fan 42, and the fresh air after heat exchange flows into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, so that the fresh air is sent into the room.
The double arrows in FIG. 1 show the flow direction of the foul air when the fresh air is supplied; the single arrow shows the direction of flow of the fresh air when it is fresh.
For example, in summer, the indoor temperature is significantly lower than the outdoor temperature, indoor foul air exchanges heat with fresh air at the total heat exchanger 43, the fresh air is introduced into the room after the temperature of the fresh air is raised, and the foul air is discharged to the outside after the temperature of the foul air is lowered.
In some embodiments, the air conditioning system may further include a purge air valve 12, and the intake air duct of the internal circulation subsystem and the exhaust air duct of the fresh air system may be selectively communicated through the purge air valve 12. In other words, the purge air valve 12 is provided between the internal circulation return air inlet 31 and the outdoor air outlet 35.
Thus, the air conditioning system can have a purification mode, in which the purification air valve 12 is opened, the fresh air valve 13 is opened, the temperature control air valve 11 is closed, the air supply fan 41 and the air exhaust fan 42 are both opened, outdoor fresh air is sucked into a fresh air duct from the outdoor fresh air inlet 34, passes through the air mixing area 45 and is sent into the room from the indoor air supply outlet 33, indoor foul air is sucked into an air inlet duct of the internal circulation subsystem from the internal circulation air return inlet 31 and is exhausted to the outside through the purification air valve 12 and the outdoor air outlet 35 in sequence. In the purification mode, the foul air and the fresh air do not need to be subjected to heat exchange by the total heat exchanger 43, so as to prevent the indoor temperature from being improperly adjusted. The purification mode is similar to the fresh air mode, except that the indoor foul air is exhausted in the purification mode without passing through the total heat exchanger 43, and the indoor foul air is exhausted to the outside through the internal circulation air return opening 31, the purification air valve 12 and the outdoor air outlet 35.
A method of controlling the air-mix of the air conditioning system according to the embodiment of the present application will be described below with reference to fig. 1 to 4.
Wherein, air conditioning system includes: the air outlet of the fresh air subsystem and the air outlet of the fresh air subsystem are both communicated with the air supply outlet of the air conditioning system through the air mixing area 45 in some embodiments. The specific structure of the air conditioning system may refer to the description of the embodiments of the air conditioning system described above.
As shown in fig. 1 and 2, the air mixing control method according to the embodiment of the present application includes controlling the opening and closing of the fresh air subsystem and the internal circulation subsystem according to a periodic signal, where each period of the periodic signal includes a first segment of signal, a second segment of signal, a third segment of signal, and a fourth segment of signal, which are sequentially arranged in time.
As shown in FIG. 2, each period of the periodic signal is T, each period comprises a first segment signal, a second segment signal, a third segment signal and a fourth segment signal, and the duration of the first segment signal is T1The second section of signal has duration t2The third section signal has the duration of t3The fourth signal has a duration t4。
The air mixing control method of the embodiment of the application comprises the following steps: determining that one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to supply air, and controlling the fresh air subsystem to be closed; determining that a second section of signal or a fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed; and determining that the other one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air.
Then, determining that the first section of signal is received, controlling the internal circulation subsystem to supply air, and controlling the fresh air subsystem to be closed; determining that a second section of signals are received, and controlling the new air subsystem and the internal circulation subsystem to be closed; determining that a third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air; and determining that the fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed, for example, the other situation is basically the same, and details are not repeated here.
As shown in fig. 2, the signal transmitting unit transmits a periodic signal.
As shown in fig. 4, when the first segment signal is received, the internal circulation subsystem supplies air, and the fresh air subsystem is turned off, so that the cold air of the internal circulation subsystem is blown into the air mixing area 45 and is sent into the room through the indoor air supply opening 33 under the driving of the air supply fan 41, thereby realizing the indoor temperature regulation.
When the second section of signals are received, the new air subsystem and the internal circulation subsystem are both closed, and the air supply fan 41 draws out the residual cold air in the air mixing area 45 and supplies the cold air into the room through the indoor air supply outlet 33.
When the third section signal is received, the internal circulation subsystem is closed, the fresh air subsystem supplies air, the fresh air is blown into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, and therefore the fresh air is sent into the room. It should be noted that, in the related art, when the internal circulation air supply is switched to the fresh air supply, condensation is easily generated in the air mixing area 45 because the temperature of the fresh air is higher than that of the cold air; according to the technical scheme, because the cold air in the first section of signal period is basically pumped away in the second section of signal period, the mixing of the cold air and the hot air can not occur in the air mixing area 45, and therefore condensation generated in the stage is eliminated.
When the fourth section of signal is received, the new air subsystem and the internal circulation subsystem are both closed, and the air supply fan 41 draws away the residual hot air (the temperature of the new air is higher than that of the new air in the internal circulation mode) in the air mixing area 45 and sends the hot air into the room through the indoor air supply outlet 33.
In the next period, when the first section of signal is received, the internal circulation subsystem supplies air, and the fresh air subsystem is closed, so that the cold air of the internal circulation subsystem is blown into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, and the indoor temperature adjustment is realized. Since the hot air (fresh air) in the third signal period of the previous period is basically pumped away in the fourth signal period, the mixing of the hot air and the cold air does not occur in the air mixing area 45, thereby eliminating the condensation generated in the period.
In the above description of the embodiment, the air supply fan 41 is used to draw the air remaining in the air mixing area 45, but it is needless to say that an independent drawing fan may be provided, and the drawing fan is connected to the air mixing area 45 and is turned on to draw the air remaining in the air mixing area when the second-stage signal and the fourth-stage signal are applied.
According to the air mixing control method of the air conditioning system, the fresh air subsystem and the internal circulation subsystem are controlled to be opened and closed alternately by setting the periodic signal, air is not supplied to the two subsystems in alternation, breathing type air mixing is achieved, condensation in an air mixing mode can be eliminated fundamentally, and use experience of the air conditioning system is improved.
In some embodiments, as shown in fig. 2, the periodic signal is a PWM (pulse width modulation) signal, the first segment signal is a high level signal, the second segment signal and the fourth segment signal are dead time, and the third segment signal is a low level signal.
Correspondingly, the air mixing control method comprises the following steps: determining to receive one of a high level signal and a low level signal, controlling the air supply of the internal circulation subsystem, and controlling the closing of the fresh air subsystem; determining that the other one of the high level signal and the low level signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air; and in the dead time, the fresh air subsystem and the internal circulation subsystem are controlled to be closed.
It should be noted that the PWM signal can accurately and conveniently realize the above-mentioned periodic control, and the PWM signal used in the embodiment of the present application includes two dead time periods in each period.
The signal transmitting unit transmits a PWM signal when VctrlWhen the signal jumps (from high level to low level or from low level to high level), a certain dead zone is insertedTime, the dead time is used to exhaust the air remaining in the previous stage.
As shown in fig. 4, at received VctrlWhen the signal is a high level signal, the internal circulation subsystem supplies air, the fresh air subsystem is closed, and the duration time is tonThus, the cold air of the internal circulation subsystem is blown into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, thereby realizing the indoor temperature adjustment.
When the dead time is received, the new air subsystem and the internal circulation subsystem are both closed, and the duration is tdeadThe blower fan 41 draws out the cold air remaining in the air mixing area 45 and sends the cold air into the room through the indoor air supply outlet 33.
At the received VctrlWhen the signal is a low level signal, the internal circulation subsystem is closed, the fresh air subsystem supplies air, and the duration time is toffThe fresh air is blown into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, so that the fresh air is sent in. It should be noted that, in the related art, when the internal circulation air supply is switched to the fresh air supply, condensation is easily generated in the air mixing area 45 because the temperature of the fresh air is higher than that of the cold air; according to the technical scheme, because the cold air in the high-level signal period is basically pumped away in the dead time, the cold air and the hot air cannot be mixed in the air mixing area 45, and therefore condensation generated in the stage is eliminated.
When the dead time is received, the new air subsystem and the internal circulation subsystem are both closed, and the duration is tdeadThe air blower 41 draws out the hot air remaining in the air mixing region 45 (the fresh air has a higher temperature than the energy generation temperature in the internal circulation mode), and sends the hot air into the room through the indoor air outlet 33.
In the next period, when a high level signal is received, the internal circulation subsystem supplies air, and the fresh air subsystem is closed, so that cold air of the internal circulation subsystem is blown into the air mixing area 45 and is sent into the room through the indoor air supply outlet 33 under the driving of the air supply fan 41, and the indoor temperature is adjusted. Since the hot air (fresh air) during the last period of the low level signal is basically drawn away during the dead time, mixing of the cold and hot air does not occur in the air mixing region 45, thereby eliminating the condensation generated at this stage.
In some embodiments, each second segment signal is equal in duration to each fourth segment signal. Therefore, the time modulation of each period is simple, and the control is convenient to realize.
In some embodiments, the air conditioning system further comprises: the air mixing area 45 and the air supply fan 41, the air outlets of the new air subsystem and the internal circulation subsystem are communicated with the indoor air supply outlet 33 of the air conditioning system through the air mixing area 45, and the air supply fan 41 is used for driving the air in the air mixing area 45 to be discharged to the indoor air supply outlet 33; the air mixing control method comprises the following steps: during the second segment signal period and the fourth segment signal period, the blower fan 41 is controlled to be turned on.
Thus, the air supply fan 41 can pump the air remained in the air mixing area 45 in the previous stage in the dead time between the inner circulation work and the fresh air work, and an independent air exhaust fan is not arranged, so that the number of parts of the air conditioning system can be reduced, and the control difficulty is reduced.
As shown in fig. 1, the internal circulation subsystem includes a temperature-controlled air valve 11, the fresh air subsystem includes a fresh air valve 13, and the air mixing control method includes: determining that one of the first section signal and the third section signal is received, controlling the temperature control air valve 11 to be opened, and controlling the fresh air valve 13 to be closed; determining that the second section of signal or the fourth section of signal is received, and controlling the temperature control air valve 11 and the fresh air valve 13 to be closed; and determining that the other one of the first section signal and the third section signal is received, controlling the temperature control air valve 11 to be closed, and controlling the fresh air valve 13 to be opened.
In other words, in the above-described embodiment: controlling the air supply of the fresh air subsystem, including controlling the opening of a fresh air valve 13; controlling the fresh air subsystem to be closed, including controlling a fresh air valve 13 to be closed; controlling the air supply of the internal circulation subsystem, including controlling the opening of a temperature control air valve 11; and controlling the internal circulation subsystem to be closed, including controlling the temperature control air valve 11 to be closed.
Therefore, condensation prevention in the air mixing mode can be achieved by simply controlling the opening and closing of the air valve, the compressor, the fan and other equipment do not need to be started back and forth, the air mixing control method is more flexible, and equipment can be prevented from being damaged.
In some embodiments, the method of controlling the mixing of air comprises: at tp<TPROTECT_POINTThe periodic signal is adjusted so that t1/t3>FPP/FIN_CIRCLEWherein, tpFor the received heat exchanger 44 temperature, T, of the internal circulation sub-systemPROTECT_POINTIs a first safety temperature, FIN_CIRCLEFor the internal circulation flow during the supply of air to the internal circulation sub-system, FPPThe fresh air flow, t, when the fresh air subsystem is supplied with air1For the duration, t, of the first segment signal in each cycle3The duration of the third segment signal in each period.
It will be appreciated that the heat exchanger temperature tpCan be measured by a temperature sensor, the first safety temperature TPROTECT_POINTThe preset value is the internal circulation flow F when the internal circulation subsystem supplies airIN_CIRCLEFresh air flow F in air supply of fresh air subsystemPPThen, according to the type of the supply fan 41 and the rotation speed of the supply fan 41 in each stage, when the rotation speeds of the supply fan 41 in the fresh air and internal circulation stages are the same, F is determinedPP/FIN_CIRCLE1, i.e. t1>t3。
With the above arrangement, when the temperature of the heat exchanger 44 is relatively low, t can be increased1/t3The ratio of (2) increases the air volume of the internal circulation and protects the heat exchanger 44.
When the periodic signal is a PWM signal, the mixed air control method comprises the following steps: at tp<TPROTECT_POINTThe periodic signal is adjusted so that ton/toff>FPP/FIN_CIRCLEWherein, tpFor the received heat exchanger 44 temperature, T, of the internal circulation sub-systemPROTECT_POINTIs a first safety temperature, FIN_CIRCLEFor the internal circulation flow during the supply of air to the internal circulation sub-system, FPPThe fresh air flow, t, when the fresh air subsystem is supplied with aironFor the duration, t, of the first segment signal in each cycleoffThe duration of the third segment signal in each period.
ton/toffD is the duty ratio of the PWM signal, that is, the duty ratio of the PWM signal of the embodiment of the present application is adjustable, and F is the same when the rotation speeds of the air supply fan 41 in the fresh air and internal circulation stages are the samePP/FIN_CIRCLE1, even if D > 0.5.
In some embodiments, the method of controlling the mixing of wind comprises: at TCRITICAL_POINT<tp<TPROTECT_POINTThe periodic signal is adjusted so that t1/t3>FPP/FIN_CIRCLE(ii) a At tp≤TCRITICAL_POINTSending a cold protection fault signal; wherein, tpTo receive the heat exchanger 44 temperature, T, of the internal circulation subsystemPROTECT_POINTIs a first safety temperature, TCRITICAL_POINTIs a second safety temperature, FIN_CIRCLEFor the internal circulation flow during the supply of air to the internal circulation sub-system, FPPThe fresh air flow, t, when the fresh air subsystem is supplied with air1For the duration, t, of the first segment signal in each cycle3The duration of the third segment signal in each period.
It will be appreciated that the heat exchanger 44 temperature tpCan be measured by a temperature sensor, the first safety temperature TPROTECT_POINTAnd a second safety temperature TCRITICAL_POINTIs a predetermined value, TCRITICAL_POINT<TPROTECT_POINTInternal circulation flow F during air supply of internal circulation subsystemIN_CIRCLEFresh air flow F in air supply of fresh air subsystemPPThen, according to the type of the supply fan 41 and the rotation speed of the supply fan 41 in each stage, when the rotation speeds of the supply fan 41 in the fresh air and internal circulation stages are the same, F is determinedPP/FIN_CIRCLE1, i.e. t1>t3。
With the above arrangement, when the temperature of the heat exchanger 44 is relatively low, t can be increased1/t3The ratio of (2) increases the air volume of the internal circulation and protects the heat exchanger 44; when the temperature of the heat exchanger 44 is too low, it is indicated that the periodic signal is "adjusted so that t1/t3>FPP/FIN_CIRCLE' control failure, external machine electric control boardA cold protection fault signal is sent to prevent damage to the heat exchanger 44.
When the periodic signal is a PWM signal, the mixed air control method comprises the following steps: at TCRITICAL_POINT<t<TPROTECT_POINTThe periodic signal is adjusted so that ton/toff>FPP/FIN_CIRCLEWhere T is the received heat exchanger 44 temperature of the internal circulation sub-system, TPROTECT_POINTIs a first safety temperature, FIN_CIRCLEFor the internal circulation flow during the supply of air to the internal circulation sub-system, FPPThe fresh air flow, t, when the fresh air subsystem is supplied with aironFor the duration, t, of the first segment signal in each cycleoffThe duration of the third segment signal in each period.
ton/toffD is the duty cycle of the PWM signal, that is, the duty cycle of the PWM signal of the embodiment of the present application is adjustable. Through the arrangement, when the temperature of the heat exchanger 44 is lower, the air quantity of the internal circulation can be increased by increasing the duty ratio D, the heat exchanger 44 is protected, and when the rotating speeds of the air supply fan 41 in the fresh air and the internal circulation stage are the same, FPP/FIN_CIRCLE1, even if D > 0.5; when the temperature of the heat exchanger 44 is too low, it is indicated that the periodic signal is "adjusted so that t1/t3>FPP/FIN_CIRCLE"control failure" sends a cold protection fault signal to the outer machine electronic control board to prevent damage to the heat exchanger 44.
The dead time of the above steps can be determined based on the following method: air flow F of air supply fan 41 based on air conditioning systemsDetermining dead time t by air duct coefficient K of indoor unit of air conditioning system, volume of indoor unit of air conditioner, flow cross-sectional area S of air supply fan 41 and response time delta t of air valvedead. The air duct coefficient K is the proportion of the volume of an air duct in an indoor unit of the air conditioning system to the volume of the indoor unit. For example, for a 1.5P air conditioning system, in the fresh air mode, K is 0.83; in the internal circulation mode, K is 0.51.
Thus, the inventors of the present application found through a large number of experiments that the dead time t isdeadShort, the air in the previous stage is not exhausted cleanly, causingCondensation; if the dead time is long, the negative pressure caused by the fan in the dead time is large, and the noise and the energy consumption are increased. The determination of the dead time tdeadThe method can determine the proper dead time t according to the specific design parameters of the air conditioning systemdeadThe air in the last stage can be discharged completely, condensation is prevented, the influence of the negative pressure of the fan on the whole air conditioning system caused by closing of the air valve in the dead time is reduced as much as possible, and noise and energy consumption are reduced.
Air flow F of air supply fan 41 based on air conditioning systemsDetermining dead time t by air channel coefficient K of indoor unit of air conditioning system, volume V of indoor unit, flow cross-sectional area S of air supply fan 41 and response time delta t of air valvedeadInvolving the application of formulas
Determining dead time t
deadWherein
It can be understood that, since the air valve has a response time Δ t, in the initial stage of the actual dead time (within the time Δ t), the air valve is not completely closed, and when the air supply fan 41 extracts the residual air in the air mixing area 45, the internal circulation air or the fresh air is extracted in the same way as in the previous stage. The above determination can ensure that the residual air can be exhausted in the dead time by increasing the response time in the theoretical time.
In some embodiments, during the current cycle, if tp≤TCRITICAL_POINTThe period T of the next period is shortened. T isCRITICAL_POINTIs a preset second safety temperature, tpIs the collected heat exchanger 44 temperature.
In other words, when cold protection occurs, it is indicated that the current period T is too long, resulting in too long a time (T) for the heat exchanger 44off) No air heat exchange is carried out; by shortening the period T, the fresh air mode duration (T) in the next period can be shortenedoff) To prevent heat exchanger44 subcooling.
In some embodiments, the period T is determined based on the lives (the number of times of switching) of the first switch RY1 and the second switch RY2, the lives (the number of times of switching) of the thermo-valve 11 and the fresh air valve 13, the life of the air conditioner, and the cooling capacity of the air conditioner.
It is understood that the longer the life (number of times of switching) of the first switch and the second switch, and the longer the life (number of times of switching) of the thermo-valve 11 and the fresh air valve 13, the shorter period T may be set, and the stronger the cooling capability of the air conditioner, the shorter period T should be set to prevent the supercooling of the heat exchanger 44.
The air mixing control method can be realized by a control circuit shown in fig. 3.
The control circuit of the embodiment of the present application, which may be used in an air conditioning system, is described below with reference to fig. 3.
Wherein, air conditioning system includes: the air outlet of the fresh air subsystem and the air outlet of the fresh air subsystem are both communicated with the air supply outlet of the air conditioning system through the air mixing area 45 in some embodiments. The specific structure of the air conditioning system may refer to the description of the embodiments of the air conditioning system described above.
As shown in fig. 3, the control circuit includes: the signal driving sub-circuit 51, the dead zone inserting sub-circuit 52, the first switch RY1, and the second switch RY 2.
The first switch RY1 is electrically connected with the fresh air subsystem, and the first switch RY1 is used for controlling the working state of the fresh air subsystem; the second switch RY2 is electrically connected with the internal circulation subsystem, and the second switch RY2 is used for controlling the working state of the internal circulation subsystem.
The input end of the signal driving sub-circuit 51 is used for receiving the PWM signal, for example, the input end of the signal driving sub-circuit 51 is used for receiving an IO port of a single chip microcomputer, and the PWM signal is generated by a timer. The signal driving sub-circuit 51 is configured to output a signal having the same phase as or the opposite phase of the incoming signal at a first output terminal and a second output terminal, respectively.
That is, the signal driving sub-circuit 51 can convert the same signal into two signals with opposite phases, and output the two signals from the first output terminal and the second output terminal respectively. The dead-band insertion sub-circuit 52 is electrically connected to the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY 2.
The first control port K11 of the first switch RY1 is electrically connected with the first output end of the signal driving sub-circuit 51, the first control port K11 of the first switch RY1 is used for accessing a signal output by the first output end, and the first switch RY1 switches the opening and closing state of the first switch RY1 according to the signal accessed by the first control port K11 of the first switch RY1, so that the working state of the fresh air subsystem is controlled. The first switch RY1 also switches the open-close state of the first switch RY1 according to the signal accessed from the second control port K12, thereby controlling the working state of the fresh air subsystem.
The first switch RY1 is arranged such that the control logic corresponding to the first control port K11 of the first switch RY1 and the control logic corresponding to the second control port K12 of the first switch RY1 are connected in series.
In other words, when the control logic corresponding to the first control port K11 of the first switch RY1 is to close the first switch RY1, and the control logic corresponding to the second control port K12 of the first switch RY1 is to close the first switch RY1, the first switch RY1 is closed; when the control logic corresponding to the first control port K11 of the first switch RY1 is to close the first switch RY1 and the control logic corresponding to the second control port K12 of the first switch RY1 is to open the first switch RY1, the first switch RY1 is opened; when the control logic corresponding to the first control port K11 of the first switch RY1 is to turn off the first switch RY1 and the control logic corresponding to the second control port K12 of the first switch RY1 is to turn off the first switch RY1, the first switch RY1 is turned off; when the control logic corresponding to first control port K11 of first switch RY1 is to open first switch RY1 and the control logic corresponding to second control port K12 of first switch RY1 is to close first switch RY1, first switch RY1 is opened.
The first control port K21 of the second switch RY2 is electrically connected with the second output end of the signal driving sub-circuit 51, the first control port K21 of the second switch RY2 is used for accessing signals output by the second output end, and the second switch RY2 switches the opening and closing state of the second switch RY2 according to the signals accessed by the first control port K21 of the second switch RY2, so that the working state of the internal circulation sub-system is controlled. The second switch RY2 also switches the on-off state of the second switch RY2 according to the signal accessed from the second control port K22, thereby controlling the working state of the internal circulation subsystem.
The second switch RY2 is provided such that the control logic corresponding to the first control port K21 of the second switch RY2 and the control logic corresponding to the second control port K22 of the second switch RY2 are connected in series.
In other words, when the control logic corresponding to first control port K21 of second switch RY2 is to close second switch RY2, and the control logic corresponding to second control port K22 of second switch RY2 is to close second switch RY2, second switch RY2 is closed; when the control logic corresponding to the first control port K21 of the second switch RY2 is to close the second switch RY2 and the control logic corresponding to the second control port K22 of the second switch RY2 is to open the second switch RY2, the second switch RY2 is opened; when the control logic corresponding to first control port K21 of second switch RY2 is to turn off second switch RY2 and the control logic corresponding to second control port K22 of second switch RY2 is to turn off second switch RY2, second switch RY2 is turned off; when the control logic corresponding to first control port K21 of second switch RY2 is to open second switch RY2 and the control logic corresponding to second control port K22 of second switch RY2 is to close second switch RY2, second switch RY2 is opened.
When the dead zone inserting sub-circuit 52 is connected with a high level signal, the first switch RY1 and the second switch RY2 are both disconnected, and correspondingly, the air is not supplied to the internal circulation sub-system and the fresh air sub-system; the mixed wind mode is enabled when the dead band insertion sub-circuit 52 switches in a low level signal.
When the dead zone insertion sub-circuit 52 receives a low-level signal and the PWM signal received at the input terminal of the signal driving sub-circuit 51 is at a high level, the first output terminal of the signal driving sub-circuit 51 outputs a high-level signal, the second output terminal of the signal driving sub-circuit 51 outputs a low-level signal, the first switch RY1 is opened, and the second switch RY2 is closed. When the control circuit is used for an air conditioning system, the fresh air subsystem does not supply air, and the internal circulation subsystem works to supply air. For example, the fresh air damper 13 may be closed, and the thermostatic damper 11 may be opened. Fresh air subsystem without blowing air
At the instant when the PWM signal changes from high to low, the dead-zone insertion sub-circuit 52 switches on high and delays for a period of time (t)dead) At this time, both the first switch RY1 and the second switch RY2 are turned off, that is, a dead zone is inserted. When the control circuit is used for an air conditioning system, the fresh air subsystem does not supply air, and the internal circulation subsystem does not supply air. For example, both the thermo-valve 11 and the fresh air valve 13 may be closed.
When the dead zone is over, when the PWM signal connected to the input terminal of the signal driving sub-circuit 51 is at low level, the first output terminal of the signal driving sub-circuit 51 outputs a low level signal, the second output terminal of the signal driving sub-circuit 51 outputs a high level signal, the first switch RY1 is closed, and the second switch RY2 is opened. When the control circuit is used for an air conditioning system, the fresh air subsystem works to supply air, and the internal circulation subsystem does not supply air. For example, the fresh air damper 13 may be opened and the thermostatic damper 11 may be closed.
At the instant when the PWM signal changes from low to high, the dead-zone insertion sub-circuit 52 switches on high and delays for a period of time (t)dead) At this time, both the first switch RY1 and the second switch RY2 are turned off, that is, a dead zone is inserted. When the control circuit is used for an air conditioning system, the fresh air subsystem does not supply air, and the internal circulation subsystem does not supply air. For example, both the thermo-valve 11 and the fresh air valve 13 may be closed.
The control circuit of the embodiment of the application divides the PWM signal into two opposite paths through the signal driving sub-circuit, can realize the alternate opening and closing of the two controlled parts, and inserts the dead zone through the dead zone inserting sub-circuit, so that the two controlled parts can also insert the dead zone time during the alternate opening and closing.
When the control circuit is used for controlling the working states of the internal circulation subsystem and the fresh air subsystem of the air conditioning system, the air mixing mode can be conveniently and accurately realized, condensation in the air mixing mode can be fundamentally eliminated, and the use experience of the air conditioning system is improved.
In some embodiments, the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY2 are used to access the switching power supply. As shown in fig. 3, the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY2 are used to access the switching power supply +12V, and the power supply port is also accessed to the current limiting resistor R24 for current limiting.
The dead zone insertion sub-circuit 52 is provided to cut off the power supply to the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY2 when a high level signal is turned on; the dead-zone insertion sub-circuit 52 is provided to turn on the power supply of the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY2 when a low level signal is turned on.
In some embodiments, as shown in fig. 3, the dead-zone insertion sub-circuit 52 includes a transistor V1, a base B of the transistor V1 is used for receiving high and low level signals, an emitter E of the transistor V1 is used for grounding, and a collector C of the transistor V1 is electrically connected to the second control port K12 of the first switch RY1 and the second control port K22 of the second switch RY 2.
As shown in fig. 3, the dead-band insertion sub-circuit 52 includes a first filter circuit electrically connected to the base of transistor V1. The first filter circuit may include a resistor R11 and a capacitor C11 connected in parallel, one end of the resistor R11 and one end of the capacitor C11 connected in parallel being connected to the base B of the transistor V1, and the other end of the resistor R11 and the other end of the capacitor C11 connected in parallel being grounded. The first filter circuit is used for filtering. The input terminal MODE _ ENABLE of the dead band insertion sub-circuit 52 may also be coupled to a current limiting resistor R21 for current limiting.
In some embodiments, as shown in fig. 3, the signal driving sub-circuit 51 includes: the input end of the signal driving sub-circuit 51 comprises a base B of the inverting triode V2 and a first input port 1B of the relay driving chip IC1, an emitter E of the inverting triode V2 is used for grounding, and a collector C of the inverting triode V2 is electrically connected with a second input port 2B of the relay driving chip IC 1; a first output terminal of the signal driving sub-circuit 51 includes the first output port 1C of the relay driving chip IC1, and a second output terminal of the signal driving sub-circuit 51 includes the second output port 2C of the relay driving chip IC 1.
By arranging the inverting triode V2, the access signals of the first input port 1B and the second input port 2B of the relay driver chip IC1 are inverted, the level signal of the first output port 1C of the relay driver chip IC1 corresponds to the level signal of the first input port 1B of the relay driver chip IC1, and the level signal of the second output port 2C of the relay driver chip IC1 corresponds to the level signal of the second input port 2B of the relay driver chip IC1, so that the first output end and the second output end of the signal driver sub-circuit 51 can output inverted signals.
In some embodiments, as shown in fig. 3, the second input port 2B of the relay driver IC1 is further connected to a power supply +3V, and a current limiting resistor R25 is connected between the power supply and the second input port 2B for limiting current.
The capacitor C14 is connected between the G port and the V port of the relay driving chip IC1, the G port of the relay driving chip IC1 is grounded, and the V port of the relay driving chip IC1 is connected with a +12V power supply.
In some embodiments, as shown in fig. 3, the signal driving sub-circuit 51 further includes: and the second filter circuit is electrically connected with the base B of the inverting triode V2. The second filter circuit may include a resistor R12 and a capacitor C12 connected in parallel, one end of the resistor R12 and one end of the capacitor C12 connected in parallel are connected to the base B of the inverting transistor V2, and the other end of the resistor R12 and the other end of the capacitor C12 connected in parallel are grounded. The second filter circuit is used for filtering. The base B of the inverting triode V2 can be connected with a current-limiting resistor R22 to limit current.
In some embodiments, as shown in fig. 3, the signal driving sub-circuit 51 further includes: and a third filter circuit electrically connected to the second input port 2B of the relay driver IC 1. The third filter circuit may include a resistor R13 and a capacitor C13 connected in parallel, one end of the resistor R13 and the capacitor C13 connected in parallel being connected to the first input port 1B of the relay driver chip IC1, and the other end of the resistor R13 and the capacitor C13 connected in parallel being grounded. The third filter circuit is used for filtering. The first input port 1B of the relay driver IC1 may also be connected to a current limiting resistor R23 for limiting current.
In some embodiments, as shown in fig. 3, the first switch RY1 may be a five-wire relay, the first control port K11 of the first switch RY1 is connected to the first output port 1C of the relay driver IC1, the second control port K12 of the first switch RY1 is connected to the switching power supply +12V and the collector C of the triode V1, the live wire access port K13 of the first switch RY1 is connected to the live wire of the power supply, the live wire control port K15 of the first switch RY1 is connected to the first device to be controlled, such as the fresh air valve 13 of the fresh air subsystem, and the other port K14 of the first switch RY1 is connected to the air.
The second switch RY2 can be a five-wire relay, the first control port K21 of the second switch RY2 is connected to the second output port 2C of the relay driving chip IC1, the second control port K22 of the second switch RY2 is connected to the switching power supply +12V and the collector C of the triode V1, the live wire access port K23 of the second switch RY2 is connected to the live wire of the power supply, the live wire control port K25 of the second switch RY2 is connected to the second device to be controlled, such as the thermo-valve 11 of the internal circulation subsystem, and the other port K24 of the second switch RY2 is connected in an air-connected mode.
As shown in fig. 3, the control circuit has terminals CN1 and CN2, a first interface of the terminal CN1 is connected to the live control port K15 of the first switch RY1, and a second interface of the terminal CN1 is connected to the neutral line; the first interface of the terminal CN2 is connected with the live wire control port K25 of the second switch RY2, and the second interface of the terminal CN2 is connected with the zero wire.
When the control circuit is used for an air conditioning system, a first interface of a live wire connecting terminal CN1 of the temperature control air valve 11 and a second interface of a zero wire connecting terminal CN1 of the temperature control air valve 11 are connected; the live wire of new trend blast gate 13 connects the first interface of terminal CN2, and the zero line of new trend blast gate 13 connects the second interface of terminal CN 2.
The application also discloses a control chip.
The control chip comprises a control circuit and a single chip microcomputer, wherein an IO interface of the single chip microcomputer is electrically connected with an input end of the signal driving sub-circuit 51 and an input end of the dead zone inserting sub-circuit 52. The control chip can generate PWM signals with adjustable duty ratios through the timer.
The application also discloses an air conditioning system.
As shown in fig. 1 to 3, the air conditioning system includes: fresh air subsystem, inner loop subsystem and control chip, control chip are the control chip of above-mentioned one embodiment, and first switch RY1 is connected with fresh air subsystem electricity, and second switch RY2 is connected with inner loop subsystem electricity.
As shown in fig. 1 to 3, the air conditioning system includes: fresh air subsystem, inner loop subsystem and control chip, control chip are the control circuit of above-mentioned one embodiment, and first switch RY1 is connected with fresh air subsystem electricity, and second switch RY2 is connected with inner loop subsystem electricity.
As shown in figure 1, the fresh air subsystem is provided with a fresh air damper 13, the internal circulation subsystem is provided with a temperature control damper 11, the first switch RY1 is electrically connected with the fresh air damper 13, and the second switch RY2 is electrically connected with the temperature control damper 11.
As shown in fig. 1, the air conditioning system has an air mixing area 45, the temperature-controlled air valve 11 is used for controlling the communication state between the internal circulation subsystem and the air mixing area 45, and the fresh air valve 13 is used for controlling the communication state between the air suction port of the fresh air subsystem and the air mixing area 45. The air outlets of the fresh air subsystem and the internal circulation subsystem are communicated with the air outlet of the air conditioning system through an air mixing area 45.
According to the air conditioning system of this application embodiment, through the control circuit who sets up above-mentioned structural style, and control two subsystems and do not all supply air between in turn, realize the mixed wind of breathing formula, can fundamentally eliminate the condensation under the mixed wind mode, improve air conditioning system's use and experience.
The following describes the air mixing control device of the air conditioning system provided in the embodiments of the present application, and the air mixing control device of the air conditioning system described below and the air mixing control method of the air conditioning system described above may be referred to in correspondence with each other.
The air conditioning system includes: internal circulation subsystem and new trend subsystem, as shown in fig. 5, this mixed wind controlling means includes: a signal receiving module 510 and a processing module 520.
The signal receiving module 510 is configured to receive a periodic signal, where each period of the periodic signal includes a first segment signal, a second segment signal, a third segment signal, and a fourth segment signal that are sequentially arranged in time. The processing module 520 is used for controlling the opening and closing of the fresh air subsystem and the internal circulation subsystem according to the periodic signals; determining to receive one of the first section signal and the third section signal, controlling the air supply of the internal circulation subsystem, and controlling the closing of the fresh air subsystem; determining that a second section of signal or a fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed; and determining that the other one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air.
According to the air mixing control device of the air conditioning system, the fresh air subsystem and the internal circulation subsystem are controlled to be opened and closed alternately by setting the periodic signal, and the two subsystems are controlled to not supply air alternately, so that condensation in an air mixing mode can be eliminated fundamentally, and the use experience of the air conditioning system is improved.
As shown in fig. 1-5, the present application also discloses an air conditioning system comprising: an internal circulation subsystem, a fresh air subsystem and the air mixing control device of the embodiment.
According to the air conditioning system provided by the embodiment of the application, the fresh air subsystem and the internal circulation subsystem are controlled to be opened and closed alternately by setting the periodic signal, and the two subsystems are controlled to not supply air alternately, so that condensation in the air mixing mode can be eliminated fundamentally, and the use experience of the air conditioning system is improved.
Fig. 6 illustrates a physical structure diagram of an electronic device, which may include, as shown in fig. 6: a processor (processor)810, a communication Interface 820, a memory 830 and a communication bus 840, wherein the processor 810, the communication Interface 820 and the memory 830 communicate with each other via the communication bus 840. The processor 810 may invoke logic instructions in the memory 830 to perform a method of controlling the mix of air in an air conditioning system, the method comprising: controlling the opening and closing of the fresh air subsystem and the internal circulation subsystem according to periodic signals, wherein each period of the periodic signals comprises a first section of signal, a second section of signal, a third section of signal and a fourth section of signal which are sequentially arranged in time; determining to receive one of the first section signal and the third section signal, controlling the air supply of the internal circulation subsystem, and controlling the closing of the fresh air subsystem; determining that a second section of signal or a fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed; and determining that the other one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air.
It should be noted that, when being implemented specifically, the electronic device in this embodiment may be a server, a PC, or other devices, as long as the structure includes the processor 810, the communication interface 820, the memory 830, and the communication bus 840 shown in fig. 6, where the processor 810, the communication interface 820, and the memory 830 complete mutual communication through the communication bus 840, and the processor 810 may call the logic instructions in the memory 830 to execute the above method. The embodiment does not limit the specific implementation form of the electronic device.
In addition, the logic instructions in the memory 830 may be implemented in software functional units and stored in a computer readable storage medium when the logic instructions are sold or used as independent products. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.
Further, the present application discloses a computer program product, the computer program product includes a computer program stored on a non-transitory computer readable storage medium, the computer program includes program instructions, when the program instructions are executed by a computer, the computer can execute the method for controlling the mixed air of the air conditioning system provided by the above method embodiments, the method includes: controlling the opening and closing of the fresh air subsystem and the internal circulation subsystem according to periodic signals, wherein each period of the periodic signals comprises a first section of signal, a second section of signal, a third section of signal and a fourth section of signal which are sequentially arranged in time; determining to receive one of the first section signal and the third section signal, controlling the air supply of the internal circulation subsystem, and controlling the closing of the fresh air subsystem; determining that a second section of signal or a fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed; and determining that the other one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air.
In another aspect, embodiments of the present application further provide a non-transitory computer-readable storage medium, on which a computer program is stored, where the computer program is implemented by a processor to execute a method for controlling mixed air of an air conditioning system provided in the foregoing embodiments, where the method includes: controlling the opening and closing of the fresh air subsystem and the internal circulation subsystem according to periodic signals, wherein each period of the periodic signals comprises a first section of signal, a second section of signal, a third section of signal and a fourth section of signal which are sequentially arranged in time; determining to receive one of the first section signal and the third section signal, controlling the air supply of the internal circulation subsystem, and controlling the closing of the fresh air subsystem; determining that a second section of signal or a fourth section of signal is received, and controlling the new air subsystem and the internal circulation subsystem to be closed; and determining that the other one of the first section of signal and the third section of signal is received, controlling the internal circulation subsystem to be closed, and controlling the fresh air subsystem to supply air.
The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.
Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods described in the embodiments or some parts of the embodiments.
Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.