CN111102685A - Sensor and air conditioner comprising same - Google Patents

Abstract

The present invention relates to a sensor and an air conditioner including the same. The sensor is used for continuously measuring the sensing signal after the whole air conditioner is powered off, so that the sensing signal can be immediately provided for the air conditioner controller when the air conditioner is started again, the air conditioner can be immediately used for mode decision according to the sensing signal, the waiting time of a user is greatly reduced, and the user experience is improved.

Description

Sensor and air conditioner comprising same

Technical Field

The invention relates to the technical field of air conditioners, in particular to a sensor and an air conditioner comprising the sensor.

Background

An air conditioner generally includes an outdoor unit and an indoor unit, which are connected to each other by pipes and are controlled to operate by a controller. A sensor (such as a temperature sensor or a humidity sensor) for the air conditioner is usually further included, and the controller controls the air conditioner to enter a corresponding operation mode after a sensing signal measured by the sensor is transmitted to the controller.

However, in the prior art, after the air conditioner is turned on, it is often necessary to wait for a period of time (e.g. 30S), and the measured value of the temperature of the sensor is stable (determined by the property detected by the sensor itself, which is relatively accurate only when the measured value is stable after a period of time is continuously detected), and then the cooling or heating mode can be determined. This undoubtedly increases the user's latency, reducing the user experience.

In addition, in the prior art, an internal controller and an external controller are usually connected through a wire, and an indoor temperature sensor and an outdoor temperature sensor are connected with one of the external controllers through the wire, and then connected with the other controller through the wire. This easily causes problems such as delay in signal transmission, an increase in load on one of the controllers, and deviation of the transmitted sensing signal due to signal interference.

Disclosure of Invention

In order to solve the above problems, according to a first aspect of the present invention, there is provided a sensor for an air conditioner, the sensor being capable of measuring a sensing signal and forming a communication link with the air conditioner through transmission interaction of the sensing signal;

and the sensor can continuously measure the sensing signal after the whole air conditioner is powered off.

According to the invention, the sensor continues to measure the sensing signal after the whole air conditioner is powered off, so that the sensing signal can be immediately provided for the air conditioner controller when the air conditioner is started again and operated, and the air conditioner can be immediately used for mode decision according to the sensing signal, thereby greatly reducing the waiting time of a user and improving the user experience.

Further, after the air conditioner is powered off, the sensor has a measurement state section capable of measuring the sensing signal and a measurement stop state section capable of stopping measuring the sensing signal.

Further, after the whole machine of the air conditioner is powered off, the sensor is switched to the measurement stopping state section after the measurement state section of a preset time interval; or after the sensor reaches a preset time node, switching from the measurement state section to the measurement stopping state section.

Further, after the sensor is switched to the measurement stopping state section, if the whole air conditioning device is still in a power-off state, the following steps are performed:

after the sensor passes a measuring stopping state section of a preset time interval, the sensor is switched to the measuring state section; or after the sensor reaches a preset time node, switching from the measurement stopping state section to the measurement state section.

Further, the sensor is a wireless sensor.

Further, the sensing signal includes temperature, and/or humidity.

Further, the sensor is a wireless temperature sensor, including: the system comprises an outdoor temperature sensor for measuring current outdoor temperature information, an indoor temperature sensor for measuring current indoor temperature information and/or a pipeline key point temperature sensor for measuring current pipeline key point temperature information.

In a second aspect of the present invention, there is also provided an air conditioning apparatus, comprising a controller, a receiver and a sensor, wherein the sensor is the sensor described above; and the controller can perform transmission interaction of the sensing signal between the receiver and the sensor.

Furthermore, after the air conditioner is started to operate, a first temperature sensing signal can be obtained from the wireless temperature sensor in real time so as to determine to operate the refrigerating or heating module; wherein the first temperature sensing signal contains the current indoor temperature information.

Furthermore, after the air conditioner is started to operate, a second temperature sensing signal can be obtained from the wireless temperature sensor in real time to determine whether to operate a defrosting mode; wherein the second temperature sensing signal contains the current outdoor temperature information.

Further, the controller comprises an internal controller and an external controller, the receiver comprises a first wireless gateway and a second wireless gateway, and the sensor comprises the indoor temperature sensor and the outdoor temperature sensor;

the indoor temperature sensor measures the current indoor temperature information and performs transmission interaction with the indoor unit controller through the first wireless gateway;

and the outdoor temperature sensor measures the current outdoor temperature information and performs transmission interaction with the external machine controller through the second wireless gateway.

Further, the pipeline key point temperature sensor performs transmission interaction between the internal machine controllers through the first wireless gateway, and/or performs transmission interaction between the external machine controllers through the second wireless gateway.

Furthermore, after the air conditioner is started to operate, a third temperature sensing signal can be obtained from the wireless temperature sensor in real time so as to determine an operation high-speed operation mode or a protection mode; the third temperature sensing signal comprises the current indoor temperature information, the current outdoor temperature information and the current pipeline key point temperature information.

Therefore, the invention can immediately provide the sensing signal to the air conditioner controller when the air conditioner is started again and operated, so that the air conditioner can immediately use the sensing signal for mode decision, thereby greatly reducing the waiting time of a user and improving the user experience.

Drawings

FIG. 1 is a schematic diagram of a communication link for transmitting and interacting sensing signals between a sensor and an air conditioner according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It should be noted that the terms "first," "second," "third," and the like in this application are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

For the purpose of facilitating an understanding of the present application, the technical solutions provided in the present application will be described in detail below with reference to specific embodiments.

The first implementation mode comprises the following steps:

the present embodiment provides a sensor for an air conditioner.

Specifically, the sensor can measure a sensing signal and form a communication connection with the air conditioning device through the transmission interaction of the sensing signal (see fig. 1); and the sensor can continue to measure the sensing signal after the whole air conditioner is powered off.

Therefore, by the embodiment, the sensing signal can be immediately provided to the air conditioner controller when the air conditioner is started again to operate, so that the air conditioner can immediately use for mode decision according to the sensing signal, the waiting time of a user is greatly reduced, and the user experience is improved.

Preferably, the sensor is a wireless sensor. Adopt wireless sensor can effectively avoid the electric potential safety hazard that the line brought (if outer machine sensor line can take the forceful electric power, if the insulation failure then easily leads to hidden danger such as strike sparks, electrocute), avoid complicated wiring, production installation inefficiency and cooperate harmfully easily to can hang down the physics restriction of avoiding the line, be convenient for arrange the sensor in the best position of sensing measurement (if indoor temperature or humidity transducer can arrange in the position that is more close to the user). And more preferably: the wireless sensor can adopt a low-power wireless connection mode (such as Bluetooth or Zigbee, z-wave and the like), and can reduce the power consumption of the sensor for keeping working for a long time under the condition of ensuring the connection distance.

Preferably, the sensing signal comprises temperature, and/or humidity. More preferably: the sensor is a temperature sensor, and the sensing signal is temperature. Further, the temperature sensor may have a plurality (see fig. 1) including: the system comprises an outdoor temperature sensor for measuring current outdoor temperature information, an indoor temperature sensor for measuring current indoor temperature information and/or a pipeline key point temperature sensor for measuring current pipeline key point temperature information. Wherein, the pipeline key points such as exhaust, outdoor coil (outer coil), return air, compressor, indoor coil (inner coil) and the like, pipeline key point temperature sensors can be arranged at one or more of the above key points. The pipeline key point temperature sensor can be fixedly arranged at the position of the pipeline key point in the air conditioner manufacturing process, and one or more indoor and outdoor temperature sensors can be arranged at the position capable of accurately measuring the indoor and outdoor temperatures in the air conditioner mounting process.

The second embodiment:

the present embodiment provides a sensor for an air conditioner, basically having the same configuration as the first embodiment described above.

The difference lies in that: the present embodiment is further preferably: after the whole air conditioner is powered off, the sensor is provided with a measuring state section capable of measuring the sensing signal and a measuring stopping state section for stopping measuring the sensing signal.

The application discovers that if the sensor keeps the working state for a long time, the problems of faults, service life reduction and the like are easily caused, and meanwhile, the waste of power consumption and energy is also caused. The application further finds that part of users usually do not use the air conditioner any more within a certain time after turning off the air conditioner, or do not use the air conditioner before certain time nodes due to the work and rest habits of the users (such as office workers who do not use the home air conditioner during the working period of the working day towards nine nights and five), and the like. Therefore, the sensor can be switched between the measuring state section and the measuring stopping state section after the whole air conditioner is powered off, so that the resources are effectively saved, the power consumption is reduced, and the service life of the sensor is prolonged.

The third embodiment is as follows:

the present embodiment provides a sensor for an air conditioner, basically having the same configuration as the second embodiment.

The difference lies in that: the present embodiment is further preferably: after the whole air conditioner is powered off, the sensor is switched to a measurement stopping state section after a measurement state section of a preset time interval. After the sensor is switched into the measurement stopping state section, if the whole air conditioner is still in the power-off state, the sensor is switched into the measurement state section after the measurement stopping state section with a preset time interval.

For example, after the air conditioner is powered off, the sensor continues to measure and work for 1 or 2 hours (a preset time interval) to avoid the problem that the user starts again in a short period and cannot quickly acquire the current sensing signal. And after the preset time interval, the user is presumed to probably not use the air conditioner any more in a subsequent period of time, so that the sensor can enter a measuring stopping state section, thereby effectively saving resources, reducing power consumption and prolonging the service life of the sensor.

The 'measurement stopping state segment is converted into the measurement state segment', which can be driven by the action of starting the air conditioner again, and at the moment, the sensor is converted into the measurement state segment and starts measurement. However, this method is not favorable for quickly acquiring the current sensing signal while the air conditioner is turned on. Therefore, it is more preferable to shift the sensor from the stop measurement state period to the measurement state period in advance before the air conditioner is turned on again.

For example, when the whole air conditioner is still in a power-off state, it is determined that the time period for the sensor to enter the measurement stop state reaches 6 or 8 hours (a predetermined time interval), and it is estimated that the user is likely to use the air conditioner, so that the sensor can be made to enter the measurement state period in advance, thereby facilitating the air conditioner to start and simultaneously rapidly acquire the current sensing signal.

In the invention, the processes of the 'measurement state stopping segment' and the 'measurement state segment' can be circularly iterated when the whole air conditioner is still in a power-off state.

The fourth embodiment:

the present embodiment provides a sensor for an air conditioner, basically having the same configuration as the third embodiment.

The difference lies in that: the present embodiment is further preferably: after the whole air conditioner is powered off, the sensor is switched to a measurement stopping state section from the measurement state section after reaching a preset time node. After the sensor is switched into the measurement stopping state section, if the whole air conditioner is still in the power-off state, the sensor is switched into the measurement state section from the measurement stopping state section after reaching a preset time node.

The preset time node can be preset when the air conditioner leaves a factory, or can be preset by a user (through a remote controller, a mobile phone APP and the like). For example, the user sets two time nodes for not using the home air conditioner from 9 am to 6 pm on a working day, and the user turns off the air conditioner from 8 am to 30 pm, and the sensor continues to operate in the measurement state section until 9 am and then shifts to the measurement stop state section from the measurement state section. And then the sensor is kept in the measurement stopping state section (if the sensor is not interrupted by the starting action of the air conditioner) until 6 pm later, and then the sensor is switched to the measurement state section from the measurement stopping state section.

Therefore, compared with the third embodiment, the third embodiment is more beneficial to accurately controlling the switching-in and the switching-out of the 'measurement stopping state section', so that under the condition of more accurately ensuring that the user experience is not influenced, resources are effectively saved, the power consumption is reduced, and the service life of the sensor is prolonged.

The fifth embodiment:

the present embodiment provides an air conditioning apparatus including a controller, a receiver, and a sensor, which may be any of the sensors of the first to fourth embodiments; and the controller can perform transmission interaction of sensing signals between the receiver and the sensor.

Therefore, the air conditioner of the embodiment can immediately provide the sensing signal to the air conditioner controller when the air conditioner is restarted, so that the air conditioner can enter the starting modes of refrigeration, heating, defrosting, high-speed operation or protection and the like without waiting, the waiting time of a user is greatly reduced, and the user experience is improved. Furthermore, under the condition of not influencing user experience, resources can be effectively saved, power consumption is reduced, and the service life of the sensor is prolonged.

Embodiment six:

the present embodiment provides an air conditioner basically having the same configuration as that of the fifth embodiment.

The difference lies in that: the present embodiment is further preferably: after the air conditioner is started to operate, a first temperature sensing signal can be acquired from the wireless temperature sensor in real time so as to determine to operate the refrigerating or heating module; the first temperature sensing signal comprises current indoor temperature information.

Therefore, according to the embodiment, the temperature measurement value of the sensor to be detected is stable (determined by the property detected by the sensor, which is only stable and relatively accurate after the measurement value is continuously detected for a period of time) without waiting for a period of time (such as 30S) after the air conditioner is started, and then the cooling or heating mode is determined. But the sensing signal (such as the current indoor temperature information) of the sensor (such as an indoor temperature sensor) can be transmitted immediately, and the cold and hot modes can be determined immediately after the computer is started, so that the waiting time of a user is greatly reduced, and the user experience is improved.

Embodiment seven:

the present embodiment provides an air conditioner basically having the same configuration as that of the fifth embodiment.

The difference lies in that: the present embodiment is further preferably: after the air conditioner is started to operate, a second temperature sensing signal can be obtained from the wireless temperature sensor in real time so as to determine whether to operate a defrosting mode; wherein the second temperature sensing signal contains current outdoor temperature information.

Therefore, by the embodiment, the heating waiting time after the air conditioner is started is not needed, the sensing signal (such as the current outdoor temperature information) of the sensor (such as the outdoor temperature sensor) can be transmitted immediately, and the defrosting mode can be started immediately, so that the waiting time of a user is greatly reduced, and the user experience is improved.

The eighth embodiment:

the present embodiment provides an air conditioner basically having the same configuration as that of the fifth embodiment.

The difference lies in that: the present embodiment is further preferably: after the air conditioner is started to operate, a third temperature sensing signal can be obtained from the wireless temperature sensor in time so as to determine an operation high-speed operation mode or a protection mode; the third temperature sensing signal comprises current indoor temperature information, current outdoor temperature information and current pipeline key point temperature information.

Therefore, through the embodiment, the temperature information of the indoor temperature sensor, the outdoor temperature sensor and the pipeline key point temperature sensor can be immediately provided for the controller without waiting for a period of time after the air conditioner is started, so that the air conditioner can immediately enter a high-speed operation mode or a protection mode after being started, the waiting time of a user is greatly reduced, and the user experience is improved.

The ninth embodiment:

the present embodiment provides an air conditioner basically having the same configuration as that of the fifth embodiment.

The difference lies in that: referring to fig. 1, the controller includes an indoor unit controller (for controlling operation of an indoor unit of an air conditioner) and an outdoor unit controller (for controlling operation of an outdoor unit of the air conditioner), the receiver includes a first wireless gateway and a second wireless gateway, and the sensor includes an indoor temperature sensor and an outdoor temperature sensor;

the indoor temperature sensor measures current indoor temperature information and performs transmission interaction with the indoor unit controller through the first wireless gateway;

and the outdoor temperature sensor measures the current outdoor temperature information and performs transmission interaction with the outdoor unit controller through the second wireless gateway.

In the prior art, an indoor unit controller and an outdoor unit controller are usually connected by a wire, and an indoor and outdoor temperature sensor is connected with one of the outdoor unit controllers and then connected with the other controller by the wire. This easily causes delay in signal transmission, an increase in load on one of the controllers, and deviation in the transmitted sensing signal due to signal interference. Therefore, the embodiment can realize independent direct transmission of the internal and external sensing signals (such as temperature), thereby effectively improving the rapidity of signal transmission and reducing the transmission deviation of the signals caused by interference.

Preferably, the pipeline key point temperature sensor performs transmission interaction between the internal controllers of the first wireless gateway and/or between the second wireless gateway and the external controllers.

More preferably, the pipeline key point temperature sensors for measuring the inner machine key points such as the temperature of the inner coil pipe and the like perform transmission interaction with the inner machine controller through the first wireless gateway, and the pipeline key point temperature sensors for measuring the outer machine key points such as the outer coil pipe, the return air, the press and the like perform transmission interaction with the outer machine controller through the second wireless gateway. Therefore, the method is favorable for improving the rapidity of signal transmission and reducing the transmission deviation of signals caused by interference.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (13)

1. A sensor for an air conditioning unit, characterized by:

the sensor can measure a sensing signal and is in communication connection with the air conditioning device through transmission interaction of the sensing signal;

and the sensor can continuously measure the sensing signal after the whole air conditioner is powered off.

2. The sensor according to claim 1, wherein the sensor has a measurement state section capable of measuring the sensing signal and a stop measurement state section for stopping measuring the sensing signal after the air conditioner is powered off.

3. The sensor of claim 2, wherein after a predetermined time interval of the measurement state period has elapsed after the air conditioning unit is powered off, the sensor transitions to the stopped measurement state period; or after the sensor reaches a preset time node, switching from the measurement state section to the measurement stopping state section.

4. The sensor according to claim 3, wherein after the sensor is shifted to the measurement stop state, if the whole air conditioner is still in a power-off state, then:

after the sensor passes a measuring stopping state section of a preset time interval, the sensor is switched to the measuring state section; or after the sensor reaches a preset time node, switching from the measurement stopping state section to the measurement state section.

5. The sensor of any one of claims 1-4, wherein the sensor is a wireless sensor.

6. The sensor of claim 5, wherein the sensing signal comprises temperature, and/or humidity.

7. The sensor of claim 6, wherein the sensor is a wireless temperature sensor comprising: the system comprises an outdoor temperature sensor for measuring current outdoor temperature information, an indoor temperature sensor for measuring current indoor temperature information and/or a pipeline key point temperature sensor for measuring current pipeline key point temperature information.

8. An air conditioning apparatus, characterized in that the air conditioning apparatus comprises a controller, a receiver and a sensor, wherein the sensor is the sensor according to any one of claims 1 to 7; and the controller can perform transmission interaction of the sensing signal between the receiver and the sensor.

9. An air conditioning unit according to claim 8, wherein the sensor is the sensor described in claim 7; after the air conditioner is started to operate, a first temperature sensing signal can be obtained from the wireless temperature sensor in real time so as to determine to operate the refrigerating or heating module; wherein the first temperature sensing signal contains the current indoor temperature information.

10. An air conditioning unit according to claim 8, wherein the sensor is the sensor described in claim 7; after the air conditioner is started to operate, a second temperature sensing signal can be obtained from the wireless temperature sensor in real time to determine whether a defrosting mode is operated or not; wherein the second temperature sensing signal contains the current outdoor temperature information.

11. An air conditioning unit according to claim 8, wherein the sensor is the sensor described in claim 7; the controller comprises an inner machine controller and an outer machine controller, the receiver comprises a first wireless gateway and a second wireless gateway, and the sensors comprise the indoor temperature sensor and the outdoor temperature sensor;

the indoor temperature sensor measures the current indoor temperature information and performs transmission interaction with the indoor unit controller through the first wireless gateway;

and the outdoor temperature sensor measures the current outdoor temperature information and performs transmission interaction with the external machine controller through the second wireless gateway.

12. The air conditioning apparatus of claim 11, wherein the pipeline key point temperature sensor communicates with the indoor unit controller via the first wireless gateway and/or communicates with the outdoor unit controller via the second wireless gateway.

13. An air conditioning unit according to claim 8, 11 or 12, characterized in that the sensor is the sensor of claim 7; after the air conditioner is started to operate, a third temperature sensing signal can be obtained from the wireless temperature sensor in real time so as to determine an operation high-speed operation mode or a protection mode; the third temperature sensing signal comprises the current indoor temperature information, the current outdoor temperature information and the current pipeline key point temperature information.

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