A wireless air conditioner and a control device thereof
By controlling the jet drive device with a wireless power receiving module and an inverter module, the problems of power cords and noise in air conditioners are solved, realizing a wirelessly powered and noiseless air conditioner, expanding the application scenarios and improving the user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- FOSHAN SHUNDE MIDEA ELECTRONICS TECH CO LTD
- Filing Date
- 2021-10-22
- Publication Date
- 2026-06-19
Smart Images

Figure CN116007141B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of air conditioning control technology, and particularly relates to a wireless air conditioner and its control device. Background Technology
[0002] Air conditioners, with their power cords, are inconvenient to move and require connection to the power grid to operate, making them unusable in situations where plugging in mains power is inconvenient, such as outdoors. Therefore, the application scenarios for air conditioners are limited. Furthermore, related technologies require air conditioners to have compressors, and the compressor motor vibrates during the cooling and heating cycle, resulting in significant vibration and noise. Summary of the Invention
[0003] The present invention provides a portable air conditioner and its control device, which at least partially solves the problems of air conditioner noise and limited usage scenarios.
[0004] In a first aspect, embodiments of the present invention provide a control device for a wireless air conditioner, the wireless air conditioner comprising: an energy storage device for accommodating energy storage material, and a jet drive device assembled in the energy storage device, the control device comprising:
[0005] Air conditioner controller;
[0006] A wireless power receiving module for electrically connecting a receiving coil, the wireless power receiving module being electrically connected to the air conditioner controller, the wireless power receiving module being driven by the air conditioner controller to transform and process the electrical energy wirelessly transmitted by the receiving coil;
[0007] The first inverter module is used for electrically connecting the jet drive device. The wireless power receiving module is electrically connected to the air conditioner controller and the wireless power receiving module. Under the drive of the air conditioner controller and the power supply of the wireless power receiving module, the first inverter module controls the jet drive device to act on the energy storage device, so that the energy storage device outputs the cold energy or heat energy released by the energy storage material.
[0008] In some embodiments, the wireless air conditioner further includes a flow divider connected to the jet drive device, and a fan for providing airflow to the flow divider device; the control device further includes:
[0009] The second inverter module is used to connect the external fan. The second inverter module is electrically connected to the air conditioner controller and the wireless power receiving module. The second inverter module is used to control the operation of the fan under the drive of the air conditioner controller and the power supply of the wireless power receiving module. The operation of the fan is used to drive the airflow at the location of the diversion device.
[0010] In some implementations, it also includes:
[0011] An air conditioning communication module is electrically connected to the air conditioning controller. The air conditioning communication module is used to communicate wirelessly with a wireless charging device or a wireless energy storage device, wherein the wireless charging device or the wireless energy storage device is used to wirelessly transmit power to the wireless air conditioner.
[0012] In some implementations, it also includes:
[0013] An auxiliary power supply for the air conditioner is electrically connected to the output terminal of the wireless power receiving module. The auxiliary power supply is used to regulate the voltage of the output power of the wireless power receiving module and to provide the regulated power to the display device of the wireless air conditioner.
[0014] In some implementations, the wireless power receiving module includes:
[0015] A bridge rectifier circuit, wherein the AC input terminal of the bridge rectifier circuit is used to electrically connect to the receiving coil;
[0016] The voltage regulation circuit has its input terminal electrically connected to the output terminal of the bridge rectifier circuit, and its output terminal electrically connected to the input terminals of the first inverter module and the second inverter module.
[0017] In some implementations, the air conditioning controller includes:
[0018] Control chip;
[0019] A rectifier drive circuit, wherein the input terminal of the rectifier drive circuit is electrically connected to the control chip, and the output terminal of the rectifier drive circuit is electrically connected to the bridge rectifier circuit;
[0020] A voltage regulating drive circuit, wherein the input terminal of the voltage regulating drive circuit is electrically connected to the control chip, and the output terminal of the voltage regulating drive circuit is electrically connected to the powered voltage regulating circuit;
[0021] A first motor drive circuit, wherein the input terminal of the first motor drive circuit is electrically connected to the control terminal of the first inverter module, and the output terminal of the first motor drive circuit is electrically connected to the control chip;
[0022] The second motor drive circuit has its input terminal electrically connected to the control terminal of the second inverter module, and its output terminal electrically connected to the control chip.
[0023] In some implementations, the air conditioning controller further includes:
[0024] The first bus voltage detection circuit has its input terminal electrically connected to the output terminal of the bridge rectifier circuit, and its output terminal electrically connected to the control chip.
[0025] In some implementations, the air conditioning controller further includes:
[0026] The second bus voltage detection circuit has its input terminal electrically connected to the output terminal of the power-receiving voltage regulation circuit, and its output terminal electrically connected to the control chip.
[0027] A bus current detection circuit, wherein the input terminal of the bus current detection circuit is electrically connected to the power-receiving voltage regulation circuit, and the output terminal of the bus current detection circuit is electrically connected to the control chip.
[0028] In some implementations, the control device further includes:
[0029] A charge / discharge voltage regulating circuit is provided, one end of which is electrically connected to the output of the bridge rectifier circuit and the input of the power receiving voltage regulating circuit, and the other end of which is electrically connected to the battery pack of the wireless air conditioner.
[0030] In some implementations, the air conditioning controller further includes:
[0031] A charge / discharge drive circuit, wherein the output terminal of the charge / discharge drive circuit is electrically connected to the charge / discharge voltage regulation circuit, and the input terminal of the charge / discharge drive circuit is electrically connected to the control chip.
[0032] A charge / discharge current detection circuit, wherein the input terminal of the charge / discharge current detection circuit is electrically connected to the charge / discharge voltage regulation circuit, and the output terminal of the charge / discharge current detection circuit is electrically connected to the control chip;
[0033] A battery voltage detection circuit, wherein the input terminal of the battery voltage detection circuit is electrically connected to the charge / discharge voltage regulation circuit, and the output terminal of the battery voltage detection circuit is electrically connected to the control chip.
[0034] Secondly, embodiments of the present invention provide a wireless air conditioner, including the control device described in any embodiment of the first aspect.
[0035] In one or more technical solutions provided by the embodiments of the present invention, an air conditioner controller is electrically connected to a wireless power receiving module for electrically connecting a receiving coil. The wireless power receiving module, driven by the air conditioner controller, transforms and processes the electrical energy wirelessly transmitted by the receiving coil. The air conditioner controller is also electrically connected to a first inverter module for electrically connecting a jet driving device. The first inverter module controls the jet driving device to act on an energy storage device, causing the energy storage device to output the cold or heat energy released by the energy storage material. Through these embodiments, the present invention achieves wireless power receiving of the air conditioner and, in the wireless power receiving state, releases cold or heat energy based on the energy storage material output by the energy storage device. This achieves wireless and noiseless operation of the air conditioner, freeing it from usage scenario limitations and improving the user experience. Attached Figure Description
[0036] To more clearly illustrate the technical solutions in the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the accompanying drawings described below are some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0037] Figure 1 This is a schematic diagram of the first structure of the air conditioner in an embodiment of the present invention;
[0038] Figure 2 This is a schematic diagram of a second structure of the air conditioner in an embodiment of the present invention;
[0039] Figure 3 for Figure 2 A schematic diagram of the power supply scenario for the central air conditioner;
[0040] Figure 4 for Figure 2 A schematic diagram of the first circuit structure of the control device;
[0041] Figure 5 for Figure 2 A schematic diagram of the second circuit structure of the control device;
[0042] Figure 6 for Figure 5 A detailed circuit diagram corresponding to the second circuit structure in the middle. Detailed Implementation
[0043] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present invention.
[0044] It should be noted that all directional indications in the embodiments of the present invention are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indications will also change accordingly.
[0045] In this invention, unless otherwise explicitly specified and limited, the terms "connection," "fixed," etc., should be interpreted broadly. For example, "fixed" can mean a fixed connection, a detachable connection, or an integral part; it can mean a mechanical connection or an electrical connection; it can mean a direct connection or an indirect connection through an intermediate medium; it can mean the internal communication of two components or the interaction between two components, unless otherwise explicitly limited. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.
[0046] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0047] Or it may implicitly indicate the number of indicated technical features. Thus, features defined with "first," "second," etc., may explicitly or implicitly include one or more of that feature. In the description of this invention, "a plurality of" means at least two, such as two, three, etc., unless otherwise explicitly specified.
[0048] For ease of description, spatial relative terms may be used in this text to describe the relationship of one element or feature relative to another element or feature as shown in the figures. These relative terms include, for example, "bottom," "front," "upper," "tilted," "lower," "top," "inner," "horizontal," "outer," etc. Such spatial relative terms are intended to include different orientations of the mechanism in use or operation, other than those depicted in the figures. For example, if the mechanism in the figure is flipped, then an element described as "below other elements or features" or "below other elements or features" will subsequently be oriented "above other elements or features" or "above other elements or features." Therefore, the example term "below" can include both upper and lower orientations. The invention is described below with reference to the accompanying drawings and specific embodiments:
[0049] This invention provides a control device 310 for a wireless air conditioner 300, used to control the wireless air conditioner 300. The invention also provides a structural reference for the wireless air conditioner 300. Figure 1As shown, the device includes: an energy storage device 330, a jet driving device 340, a flow splitting device 350, a control device 310, and a receiving coil Lr1. The receiving coil Lr1 is electrically connected to the control device 310, and the control device 310 is connected to the jet driving device 340. Under the control of the control device 310, the jet driving device 340 applies a force to the energy storage device 330. The energy storage device 330 is used to contain energy storage material; the jet driving device 340 is mounted on the energy storage device 330; the flow splitting device 350 is connected to the energy storage device 330 through the jet driving device 340. When the jet driving device 340 applies a force to the energy storage device 330, the energy storage device 330 jets energy storage material into the flow splitting device 350, and the jetted energy storage material is dispersed and emitted in the flow splitting device 350 to release thermal or cold energy.
[0050] Specifically, the energy storage material can be a phase change energy storage material. For air conditioner 300, which is a refrigeration air conditioner, the energy storage device 330 contains a phase change cold storage material. For air conditioner 300, which is a heat pump air conditioner, the energy storage device 330 contains a phase change heat storage material. Specifically, the phase change energy storage material contained in the energy storage device 330 is a reactive heating or cooling material, which can be: a solid (nitrate, lithium bromide, etc.) or liquid solute (such as ammonia) fused with water for cooling, or quicklime oxidation for heat release.
[0051] In some implementations, in order to store phase change energy storage materials, the energy storage device 330 includes: a sealed tank 331 and a liquid spraying pipe 332. The sealed tank 331 is filled with phase change cold storage or phase change heat storage materials under high pressure. The liquid inlet of the liquid spraying pipe 332 is connected to the sealed tank 331, and the liquid outlet of the liquid spraying pipe 332 is connected to the diversion device 350. The spraying drive device 340 is mounted on the liquid spraying pipe 332 and can apply force to the liquid spraying pipe 332 to spray the phase change energy storage materials from the sealed tank 331 through the liquid spraying pipe 332 to the diversion device 350.
[0052] In some embodiments, the spray drive device 340 includes: an opening adjustment member 341 and a first motor 342. The opening adjustment member 341 is mounted on the spray pipe 332 of the energy storage device 330; the first motor 342 is connected to the opening adjustment member 341, and the operation of the first motor 342 is used to adjust the opening of the opening adjustment member 341, thereby changing the direction of the spray pipe 332 towards the diversion device 350.
[0053] The flow rate of the injected energy storage material.
[0054] Specifically, the opening adjustment component 341 can be a device that adjusts the opening evenly by pressing. This device can be a stroke-type structure, a knob-type structure, or other structures that allow the opening of the spray pipe 332 to be adjusted by pressing. All of the above-mentioned opening adjustment components 341 can achieve uniform opening adjustment by being driven by the operation of the first motor 342. The larger the opening of the opening adjustment component 341, the greater the flow rate of the energy storage material sprayed into the diversion device 350 through the spray pipe 332, and the better the cooling or heating effect of the wireless air conditioner. Conversely, the smaller the opening, the smaller the flow rate of the energy storage material sprayed into the diversion device 350 through the spray pipe 332. By combining the opening adjustment component 341 and the first motor 342, the cooling and heating effects can be adjusted.
[0055] In some implementations, the control device 310 is electrically connected to the first motor 342. The control device 310 controls the operation of the first motor 342, thereby accurately controlling the opening adjustment component 341 to uniformly adjust the opening, and thus precisely controlling the flow rate of the energy storage device 330 spraying energy storage material into the diversion device 350.
[0056] It should be understood that the first motor 342 can be any of the following motors: single-phase asynchronous motor, induction motor, brushed DC motor, single-phase brushless DC motor, three-phase brushless DC motor, three-phase permanent magnet synchronous motor, synchronous reluctance motor, and switched reluctance motor. The choice can be made according to actual needs and is not restricted here.
[0057] In some implementations, such as Figure 1 As shown, the wireless air conditioner 300 also includes a fan 360. The fan 360 is positioned opposite the distribution device 350. The operation of the fan 360 drives the airflow at the location of the distribution device 350. This airflow causes the cold or heat energy released by the distribution device 350 to flow, facilitating heat exchange with the environment. This allows the cold / heat released by the energy storage material in the distribution device 350 to be transferred further. The fan 360's airflow to the distribution device 350 increases the speed of airflow through the device, thereby allowing the cold / heat released by the energy storage material in the distribution device 350 to be transferred further, expanding the air conditioning's effective range.
[0058] For details, please refer to Figure 3 , Figure 4 As shown, in order to precisely control the operation of the fan 360, the control device 310 is electrically connected to the second motor 361 of the fan 360. The control device 310 is used to control the operation of the second motor 361, thereby controlling the angle and / or air volume of the fan 360 facing away from or towards the diversion device 350, so as to change the air flow speed at the location of the diversion device 350, thereby increasing the heat exchange speed and thus improving the comfort of the air conditioning.
[0059] It should be understood that the second motor 361 of the fan 360 can be any one of the following: single-phase asynchronous motor, induction motor, brushed DC motor, single-phase brushless DC motor, three-phase brushless DC motor, three-phase permanent magnet synchronous motor, synchronous reluctance motor, or switched reluctance motor.
[0060] Specifically, such as Figure 1 As shown, the diversion device 350 in this embodiment of the invention includes multiple parallel diversion sub-pipes 351. Each diversion sub-pipe 351 is connected to the spray port of the spray pipe 332. The diversion sub-pipes 351 can be spaced apart or have their pipe walls in contact, so as to disperse the energy storage material through the diversion device 350 as much as possible and increase the range of cold or heat energy released by the sprayed energy storage material.
[0061] The receiving coil Lr1 of the wireless air conditioner 300 is used to receive electrical energy wirelessly transmitted from an external power supply device; wherein, the external power supply device can be a wireless charging device 100 or a wireless energy storage device 200. The wireless charging device 100 can wirelessly transmit grid power when connected to the power grid, and the wireless energy storage device 200 captures and stores the electrical energy wirelessly transmitted by the wireless charging device 100, so as to wirelessly supply power to the wireless air conditioner 300 when it needs power, or the wireless air conditioner 300 can capture the electrical energy wirelessly transmitted by the wireless charging device 100.
[0062] In some implementations, the receiving coil Lr1 of the wireless air conditioner 300 is electrically connected to the control device 310. The control device 310 is used to convert the electrical energy captured by the receiving coil Lr1 into electrical energy to supply power to the load of the wireless air conditioner 300. The load of the wireless air conditioner 300 may include at least a first motor 342, and may also include a second motor 361 and / or a display device 390 in addition to the first motor 342.
[0063] In some implementations, to improve the portability of the wireless air conditioner 300, so that the wireless air conditioner 300 is not limited by the application scenario, it can be used offline and portable, for example, in an indoor kitchen or balcony, or in outdoor tents or fishing scenarios. (Reference) Figure 2 As shown, the wireless air conditioner 300 may also include a battery pack 320.
[0064] The battery pack 320 is electrically connected to the control device 310. The control device 310 is used to convert the electrical energy captured by the receiving coil Lr1 and store the converted electrical energy in the battery pack 320, or to convert the electrical energy released from the battery pack 320 and supply power to the load of the wireless air conditioner 300.
[0065] Specifically, when the receiving coil Lr1 does not receive electrical energy wirelessly output from the external power supply device (electrical energy wirelessly transmitted by the wireless charging device 100 or the wireless energy storage device 200), the battery pack 320 releases electrical energy, and the control device 310 converts the electrical energy released by the battery pack 320 into the electrical energy required by the load of the wireless air conditioner 300, and then supplies power to the load of the wireless air conditioner 300.
[0066] Specifically, when the receiving coil Lr1 receives electrical energy wirelessly output from an external power supply device, if the battery pack 320 needs charging, the control device 310 can convert the electrical energy received by the receiving coil Lr1 and store it in the battery pack 320. When the receiving coil Lr1 receives electrical energy wirelessly output from an external power supply device, if the wireless air conditioner 300 needs power, the control device 310 can also convert the electrical energy received by the receiving coil Lr1 into the electrical energy required by the load of the wireless air conditioner 300 and supply power to the corresponding load.
[0067] The circuit structure of the control device 310 will be described in detail below to help those skilled in the art understand the process and principle of the control device 310 controlling the wireless air conditioner 300:
[0068] For details, please refer to Figure 4 As shown, the control device 310 in this embodiment of the invention includes: an air conditioner controller 312, a wireless power receiving module 311, and a first inverter module 314.
[0069] The wireless power receiving module 311 is electrically connected to the air conditioning controller 312. The input end of the wireless power receiving module 311 is electrically connected to the receiving coil Lr1, and the output end of the wireless power receiving module 311 is electrically connected to the injection drive device 340 through the first inverter module 314. The first inverter module 314 is also electrically connected to the air conditioning controller 312. Thus, under the drive of the air conditioning controller 312 and the power supply of the wireless power receiving module 311, the first inverter module 314 controls the injection drive device 340 to act on the energy storage device 330, so that the energy storage device 330 injects energy storage material into the diversion device 350.
[0070] refer to Figure 4 As shown, in some embodiments, the control device 310 may further include a second inverter module 315 for controlling the fan 360.
[0071] Specifically, the second inverter module 315 is electrically connected to the air conditioner controller 312 and the wireless power receiving module 311. Under the drive of the air conditioner controller 312 and the power supply of the wireless power receiving module 311, the second inverter module 315 controls the operation of the fan 360 so that the fan 360 discharges air towards or away from the diversion device 350 and / or controls the air volume of the fan 360.
[0072] Combination Figure 6 As shown, the second inverter module 315 can be an IPM2 (Intelligent Power Module) power device. Similarly, the first inverter module 314 can be an IPM1 power device, or more simply, it can be replaced by other types of transistors, to control whether the first motor 342 and the second motor 361 are running, but not to control the specific operating parameters of the first motor 342 and the second motor 361.
[0073] refer to Figure 6 As shown, in order to drive the first motor 342, the control device 310 further includes: a first motor drive circuit 3124, the input terminal of the first motor drive circuit 3124 is electrically connected to the control terminal of the first inverter module 314, and the output terminal of the first motor drive circuit 3124 is electrically connected to the control chip 3121. The first motor drive circuit 3124 drives the first motor 342 to operate through the pulse signal output by the control chip 3121.
[0074] refer to Figure 6 As shown, in order to drive the second motor 361, the control device 310 further includes: a second motor drive circuit 3125, the input terminal of the second motor drive circuit 3125 is electrically connected to the control terminal of the second inverter module 315, and the output terminal of the second motor drive circuit 3125 is electrically connected to the control chip 3121. The second motor drive circuit 3125 is activated by the pulse signal output by the control chip 3121.
[0075] refer to Figure 6 As shown, in some embodiments, the wireless power receiving module 311 includes a bridge rectifier circuit 3111 and a power receiving voltage regulating circuit 3112. The AC input terminal of the bridge rectifier circuit 3111 is electrically connected to the receiving coil Lr1. The AC input terminal of the bridge rectifier circuit 3111 is electrically connected to the receiving coil Lr1 to rectify the electrical energy received by the receiving coil Lr1. The input terminal of the power receiving voltage regulating circuit 3112 is electrically connected to the output terminal of the bridge rectifier circuit 3111, and the output terminal of the power receiving voltage regulating circuit 3112 is electrically connected to the input terminals of the first inverter module 314 and the second inverter module 315. The power receiving voltage regulating circuit 3112 is used to step down or step up the electrical energy output by the bridge rectifier circuit 3111, and then transmit the stepped-down electrical energy to the input terminals of the first inverter module 314 and the second inverter module 315.
[0076] like Figure 6As shown, the bridge rectifier circuit 3111 is used to convert the electrical energy received by the receiving coil Lr1 from AC to DC to DC bus voltage +VDC1; after the DC bus voltage +VDC1 is further converted (boosted or bucked) by the voltage regulating circuit 3112, it becomes the DC bus voltage +VDC2 required by the first inverter module 314 and / or the second inverter module 315.
[0077] refer to Figure 6 As shown, in some embodiments, the bridge rectifier circuit 3111 may include a resonant capacitor C, a bridge rectifier, and a first filter capacitor E1. One end of the resonant capacitor C is electrically connected to one AC input terminal of the bridge rectifier, and the other end of the resonant capacitor C is electrically connected to one end of the receiving coil Lr1. The other AC input terminal of the bridge rectifier is electrically connected to the other end of the receiving coil Lr1. The two DC output terminals of the bridge rectifier are electrically connected to the positive and negative terminals of the first filter capacitor E1, respectively, and the negative terminal of the first filter capacitor E1 is grounded.
[0078] Among them, the bridge rectifier can be any of the hardware topologies of a full-bridge synchronous rectifier, a half-bridge synchronous rectifier, and an uncontrolled rectifier.
[0079] For example, refer to Figure 6 As shown, the bridge rectifier can be a full-bridge synchronous rectifier composed of a first power device Q1, a second power device Q2, a third power device Q3, and a fourth power device Q4. The power devices Q1, Q2, Q3, and Q4 can be any type of transistor, such as an IGBT (Insulated Gate Bipolar Transistor), a MOSFET, or a bipolar transistor.
[0080] To drive the bridge rectifier circuit 3111, such as Figure 6 As shown, the air conditioner controller 312 includes: a control chip 3121; and a rectifier drive circuit 3122. The input terminal of the rectifier drive circuit 3122 is electrically connected to the control chip 3121, and the output terminal of the rectifier drive circuit 3122 is electrically connected to the bridge rectifier circuit 3111. Specifically, the rectifier drive circuit 3122 is electrically connected to the gate control terminal of each power device Q1, Q2, Q3, and Q4 in the bridge rectifier circuit 3111 to control the on / off state of the power devices Q1, Q2, Q3, and Q4.
[0081] Specifically, the power receiving voltage regulation circuit 3112 can be a separate boost circuit, a separate buck circuit, or both buck and boost circuits, or a buck-boost multiplexed circuit. In practical applications, the power receiving voltage regulation circuit 3112 may not be provided; that is, the wireless power receiving module 311 may only have a bridge rectifier circuit 3111, and the output of the bridge rectifier circuit 3111 may be directly electrically connected to the first inverter module 314 and the second inverter module 315.
[0082] For example, refer to Figure 6 As shown, the voltage regulating circuit 3112 can be a step-up / step-down multiplexing circuit composed of the fifth power device Q5, the first inductor L2, the sixth power device Q6, and the second filter capacitor E2. The negative terminal of the second filter capacitor E2 is grounded. By switching the fifth power device Q5 and the sixth power device Q6 on and off, the step-up or step-down processing can be achieved.
[0083] Correspondingly, in order to drive the powered voltage regulating circuit 3112, refer to Figure 6 As shown, the air conditioner controller 312 also includes a voltage regulating drive circuit 3123. The input terminal of the voltage regulating drive circuit 3123 is electrically connected to the control chip 3121, and the output terminal of the voltage regulating drive circuit 3123 is electrically connected to the control terminal of each power device Q5 and Q6 in the voltage regulating circuit, so as to control the on and off of the fifth power device Q5 and the sixth power device Q6.
[0084] In some implementations, the wireless air conditioner 300 includes an air conditioner communication module 316 electrically connected to the air conditioner controller 312. The air conditioner communication module 316 communicates with an external power supply device that wirelessly supplies power to the wireless air conditioner 300, controlling the external power supply device to be in standby or power transmission mode. Specifically, the air conditioner communication module 316 can be one or more of the following: a Bluetooth module, a signal carrier module, an infrared transceiver module, a Wi-Fi module, a mobile communication module, a radio frequency module, and a radio module.
[0085] In some implementations, refer to Figure 2 As shown, the wireless air conditioner 300 also includes a display device 390, and the control device 310 also includes an air conditioner auxiliary power supply 317, which is electrically connected to the output terminal of the wireless power receiving module 311. The air conditioner auxiliary power supply 317 is used to regulate the DC power output by the wireless power receiving module 311 and provide the regulated DC power to the display device 390 of the wireless air conditioner 300.
[0086] Specifically, the air conditioner auxiliary power supply 317 can be electrically connected to the output terminal of the bridge rectifier circuit 3111 or the output terminal of the voltage regulating circuit 3112 to step down the DC bus voltage +VDC1 or DC bus voltage +VDC2 to obtain the voltage required by the display device 390 and supply power to the display device 390.
[0087] If the wireless air conditioner 300 in this embodiment of the invention further includes a battery pack 320, wherein the battery pack 132 includes a battery module 321 and a BMS (Battery Management System) board 322. The BMS board can provide protection functions such as charging overvoltage, charging overcurrent, discharging overcurrent, under-discharge voltage, and over-temperature for the battery module 1321, as well as power display functions.
[0088] refer to Figure 5 As shown, the control device 310 also includes a charge / discharge voltage regulation circuit 313. One end of the charge / discharge voltage regulation circuit 313 is electrically connected to the output terminal of the bridge rectifier circuit 3111 and the input terminal of the power receiving voltage regulation circuit 3112, and the other end is electrically connected to the battery pack 320. When the battery pack 320 needs to supply power to the load of the wireless air conditioner 300, the electrical energy released by the battery pack 320 undergoes DC-DC conversion through the charge / discharge voltage regulation circuit 313, and then undergoes DC-DC conversion through the power receiving voltage regulation circuit 3112 before supplying power to at least one load of the wireless air conditioner 300. When the battery pack 320 needs to be charged, the electrical energy received by the receiving coil Lr1 undergoes AC-DC conversion through the bridge rectifier circuit 3111, and then undergoes DC-DC conversion through the charge / discharge voltage regulation circuit 313 before charging the battery pack 320.
[0089] The charge / discharge voltage regulation circuit 313 is used to convert the electrical energy output from the bridge rectifier circuit 3111 into electrical energy with voltage Vb+, and store the converted electrical energy in the battery pack 320, or convert the electrical energy released from the battery pack 320 and output it to the power receiving voltage regulation circuit 3112; the power receiving voltage regulation circuit 3112 boosts the electrical energy output from the charge / discharge voltage regulation circuit 313 and supplies power to the first inverter module 314 and the second inverter module 315.
[0090] Specifically, the charge / discharge voltage regulation circuit 313 is a buck-boost multiplex circuit. (See reference) Figure 6For example, the charge / discharge voltage regulation circuit 313 can be composed of a third filter capacitor E3, a third inductor L3, a seventh power device Q7, and an eighth power device Q8. The positive and negative terminals of the third filter capacitor E3 are electrically connected to the positive and negative terminals of the battery pack 320, and the negative terminal of the third filter capacitor E3 is grounded. By changing the on / off state of the seventh power device Q7 and the eighth power device Q8, one of the two methods of voltage boosting and voltage bucking can be achieved.
[0091] In order to control the on / off state of the seventh power device Q7 and the eighth power device Q8, the air conditioning controller 312 further includes: a charge / discharge drive circuit 312a; the output terminal of the charge / discharge drive circuit 312a is electrically connected to the gate control terminal of the seventh power device Q7 and the eighth power device Q8, and the output terminal of the charge / discharge drive circuit 312a is electrically connected to the control chip 3121, so that the control chip 3121 drives the on / off state of the seventh power device Q7 and the eighth power device Q8.
[0092] In some implementations, in order to monitor the transformation process of the wireless power receiving module 311 and accurately control its power conversion, the air conditioner controller 312 in this embodiment of the invention further includes a first bus voltage detection circuit 3126, a second bus voltage detection circuit 3127, and a bus current detection circuit 312b.
[0093] The input terminal of the first bus voltage detection circuit 3126 is electrically connected to the output terminal of the bridge rectifier circuit 3111. The first bus voltage detection circuit 3126 detects the voltage value +VDC1 of the electrical energy after the bridge rectifier circuit 3111 performs power conversion and provides it to the control chip 3121. The control chip 3121 controls the rectifier drive circuit 3122 based on the voltage value +VDC1 fed back by the first bus voltage detection circuit 3126, and then controls the on / off state of each power device Q1, Q2, Q3, Q4 in the bridge rectifier circuit 3111, thereby controlling the rectification process of the bridge rectifier circuit 3111.
[0094] The output of the second bus voltage detection circuit 3127 is electrically connected to the control chip 3121; the input of the second bus voltage detection circuit 3127 is electrically connected to the output of the voltage-regulating circuit 3112, and the output of the second bus voltage detection circuit 3127 is electrically connected to the control chip 3121 to detect the voltage value +VDC2 of the electrical energy after the voltage-regulating circuit 3112 performs electrical energy conversion, and provide it to the control chip 3121. The input of the bus current detection circuit 312b is electrically connected to the voltage-regulating circuit 3112, and the output of the bus current detection circuit 312b is electrically connected to the control chip 3112. Specifically, a first resistor R1 is electrically connected between the emitter of the sixth power device Q6 and the negative terminal of the second filter capacitor E2, and the input of the bus current detection circuit 312b is electrically connected to the first resistor R1 to detect the current of the voltage-regulating circuit 3112 and provide it to the control chip 3121.
[0095] The control chip 3121 controls the on / off state of each power device Q5 and Q6 in the power receiving voltage regulation circuit 3112 based on the voltage value +VDC2 fed back by the second bus voltage detection circuit 3127 and the control voltage regulation drive circuit 3123, thereby controlling the voltage regulation process of the power receiving voltage regulation circuit 3112.
[0096] In some implementations, in order to monitor the conversion process of the charge-discharge voltage regulation circuit 313 and accurately control its power conversion, the air conditioner controller 312 further includes a charge-discharge current detection circuit 3128 and a battery voltage detection circuit 3129.
[0097] The input terminal of the charge / discharge current detection circuit 3128 is electrically connected to the charge / discharge voltage regulation circuit 313, and the output terminal of the charge / discharge voltage regulation circuit 313 is electrically connected to the control chip 3121. The input terminal of the battery voltage detection circuit 3129 is electrically connected to the charge / discharge voltage regulation circuit 313, and the output terminal of the battery voltage detection circuit 3129 is electrically connected to the control chip 3121. The charge / discharge current detection circuit 3128 and the battery voltage detection circuit 3129 respectively detect the battery voltage and the charge / discharge current of the charge / discharge voltage regulation circuit 313. Based on the detected values, the control chip 3121 controls the on / off switching of each power device Q7 and Q8 in the charge / discharge voltage regulation circuit 313, thereby controlling the voltage regulation process of the power receiving voltage regulation circuit 3112.
[0098] The control device 310 provided in this embodiment of the invention realizes the processing and control of the wireless power receiving process of the wireless air conditioner 300, as well as the release of cold or heat by the pressure-injected energy storage phase change material under wireless power receiving, and reasonably controls the power supply to the load of the air conditioner and the operation of the pressure-injected energy storage phase change material according to the actual scenario.
[0099] The above description is merely an embodiment of the present invention and is not intended to limit the invention. Various modifications and variations can be made to the present invention by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the scope of the claims of the present invention.
Claims
1. A control device for a wireless air conditioner, characterized by comprising: The wireless air conditioner includes: an energy storage device for containing energy storage material, and a jet driving device assembled in the energy storage device. The jet driving device includes an opening adjustment component and a first motor. The opening adjustment component is assembled in the liquid injection pipe of the energy storage device. The operation of the first motor is used to adjust the opening of the opening adjustment component to change the flow rate of the energy storage material injected through the liquid injection pipe. The control device includes: Air conditioner controller; A wireless power receiving module for electrically connecting a receiving coil, the wireless power receiving module being electrically connected to the air conditioner controller, the wireless power receiving module being driven by the air conditioner controller to transform and process the electrical energy wirelessly transmitted by the receiving coil; The first inverter module is used to electrically connect the first motor. The first inverter module is electrically connected to the air conditioner controller and the wireless power receiving module. Under the drive of the air conditioner controller and the power supply of the wireless power receiving module, the first inverter module controls the jet drive device to act on the energy storage device so that the energy storage device outputs the cold energy or heat energy released by the energy storage material. An air conditioning communication module is electrically connected to the air conditioning controller. The air conditioning communication module is used to communicate with an external power supply device that wirelessly supplies power to the wireless air conditioner, so as to control the external power supply device that wirelessly supplies power to the wireless air conditioner to be in standby or energy transmission state.
2. The control device of claim 1, wherein The wireless air conditioner further includes a flow distribution device connected to the jet drive device, and a fan for providing airflow to the flow distribution device. The control device further includes: The second inverter module is used to connect the external fan. The second inverter module is electrically connected to the air conditioner controller and the wireless power receiving module. The second inverter module is used to control the operation of the fan under the drive of the air conditioner controller and the power supply of the wireless power receiving module. The operation of the fan is used to drive the airflow at the location of the diversion device.
3. The control device according to claim 1 or 2, characterized by Also includes: An auxiliary power supply for the air conditioner is electrically connected to the output terminal of the wireless power receiving module. The auxiliary power supply is used to regulate the voltage of the output power of the wireless power receiving module and to provide the regulated power to the display device of the wireless air conditioner.
4. The control device of claim 2, wherein The wireless power receiving module includes: A bridge rectifier circuit, wherein the AC input terminal of the bridge rectifier circuit is used to electrically connect to the receiving coil; The voltage regulation circuit has its input terminal electrically connected to the output terminal of the bridge rectifier circuit, and its output terminal electrically connected to the input terminals of the first inverter module and the second inverter module.
5. The control device as described in claim 4, characterized in that, The air conditioner controller includes: Control chip; A rectifier drive circuit, wherein the input terminal of the rectifier drive circuit is electrically connected to the control chip, and the output terminal of the rectifier drive circuit is electrically connected to the bridge rectifier circuit; A voltage regulating drive circuit, wherein the input terminal of the voltage regulating drive circuit is electrically connected to the control chip, and the output terminal of the voltage regulating drive circuit is electrically connected to the powered voltage regulating circuit; A first motor drive circuit, wherein the input terminal of the first motor drive circuit is electrically connected to the control terminal of the first inverter module, and the output terminal of the first motor drive circuit is electrically connected to the control chip; The second motor drive circuit has its input terminal electrically connected to the control terminal of the second inverter module, and its output terminal electrically connected to the control chip.
6. The control device of claim 5, wherein The air conditioner controller also includes: The first bus voltage detection circuit has its input terminal electrically connected to the output terminal of the bridge rectifier circuit, and its output terminal electrically connected to the control chip.
7. The control device of claim 6, wherein The air conditioner controller also includes: The second bus voltage detection circuit has its input terminal electrically connected to the output terminal of the power-receiving voltage regulation circuit, and its output terminal electrically connected to the control chip. A bus current detection circuit, wherein the input terminal of the bus current detection circuit is electrically connected to the power-receiving voltage regulation circuit, and the output terminal of the bus current detection circuit is electrically connected to the control chip.
8. The control device as described in claim 6, characterized in that, The control device further includes: A charge / discharge voltage regulating circuit is provided, one end of which is electrically connected to the output of the bridge rectifier circuit and the input of the power receiving voltage regulating circuit, and the other end of which is electrically connected to the battery pack of the wireless air conditioner.
9. The control device of claim 8, wherein The air conditioner controller also includes: A charge / discharge drive circuit, wherein the output terminal of the charge / discharge drive circuit is electrically connected to the charge / discharge voltage regulation circuit, and the input terminal of the charge / discharge drive circuit is electrically connected to the control chip. A charge / discharge current detection circuit, wherein the input terminal of the charge / discharge current detection circuit is electrically connected to the charge / discharge voltage regulation circuit, and the output terminal of the charge / discharge current detection circuit is electrically connected to the control chip; A battery voltage detection circuit, wherein the input terminal of the battery voltage detection circuit is electrically connected to the charge / discharge voltage regulation circuit, and the output terminal of the battery voltage detection circuit is electrically connected to the control chip.
10. A wireless air conditioner, characterized by comprising: Includes the control device as described in any one of claims 1-9.