Patent Application
20220395155
This application claims the priority benefit of Taiwan application serial no. 110121028, filed on Jun. 9, 2021. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
The present disclosure relates to an electronic device, particularly to a suction device and a suction force adjustment method thereof.
As the technology continues to advance, vacuum cleaners and sweeping robots that automatically vacuum fine dirt and charge themselves have become quite a common view. However, the cleaning effects of these tools may not be ideal, as the suction force of the vacuum cleaner may be compromised by an environment of a high degree of dirtiness or the excessive accumulation of dust. Although sweeping the same area repeatedly is a way to improve the cleaning result, it still takes more time and power to complete the task.
The disclosure provides a suction device and a suction force adjustment method thereof capable of effectively improving the suction efficiency of a suction device.
The suction device of the disclosure includes a suction pipe, a suction unit, an optical detection unit, and a control host. The suction unit is connected to the suction pipe and is adapted to provide a suction force in the suction pipe to suck an object. The optical detection unit is disposed on a suction path of the suction pipe and detects the object flowing through the suction pipe. The optical detection unit includes at least one linear light source and at least one sensor group. The linear light source provides a light curtain formed by multiple beams. The light curtain is located on the suction path, and the object passes through the light curtain along the suction path. The linear light source and the sensor group are disposed on both sides of the suction path, and the sensor group senses the beams uninterrupted by the object to generate a sensing signal. The control host is coupled to the suction unit, the linear light source, and the sensor group. The control host determines physical features of the object according to the sensing signal and regulates the suction force of the suction unit based on the physical features of the object.
In an embodiment of the disclosure, the control host further displays an image of the object according to the sensing signal.
In an embodiment of the disclosure, the physical features of the object include at least one of transparency, quantity, density, shape, and size of the object.
In an embodiment of the disclosure, the beams are visible light or invisible light, and the sensor group includes a visible light sensor or an invisible light sensor.
In an embodiment of the disclosure, the control host further adjusts operating parameters of the linear light source and the sensor group according to the suction force of the suction unit.
In an embodiment of the disclosure, the operating parameters of the linear light source and the sensor group include the frequency of enabling the linear light source and the sensor group, the beam intensity of the linear light source, and the sensitivity of the sensor group.
In an embodiment of the disclosure, the suction device further includes a remote control device to communicate wirelessly with the control host, receive and store at least one of status information of the suction device and feature information of the object, analyze at least one of the status information of the suction device and the feature information of the object, and issue a suction-force adjustment command to the control host based on an analysis result.
In an embodiment of the disclosure, the feature information of the object includes image data of the object, and the remote control device displays an image of the object according to the image data of the object.
The disclosure further provides a suction force adjustment method for a suction device including a suction unit and a suction pipe connected to the suction unit, and a suction force is provided in the suction pipe to suck an object. The suction force adjustment method for the suction device includes the following steps. At least one linear light source is provided, and the linear light source provides a light curtain formed by multiple beams. The light curtain is located on the suction path of the suction pipe, and the object passes through the light curtain along the suction path. At least one sensor group is provided. The linear light source and the sensor group are disposed on both sides of the suction path, and the sensor group senses the beams uninterrupted by the object to be tested to generate a sensing signal. Physical features of the object are determined according to the sensing signal. The suction force of the suction unit is regulated based on the physical features of the object.
In an embodiment of the disclosure, the suction force adjustment method of the suction device includes displaying an image of the object according to the sensing signal.
In an embodiment of the disclosure, the physical features of the object include at least one of transparency, quantity, density, shape, and size of the object.
In an embodiment of the disclosure, the beams are visible light or invisible light, and the sensor group includes a visible light sensor or an invisible light sensor.
In an embodiment of the disclosure, the suction force adjustment method of the suction device includes adjusting operating parameters of the linear light source and the sensor group according to the suction force of the suction unit.
In an embodiment of the disclosure, the operating parameters of the linear light source and the sensor group include the frequency of enabling the linear light source and the sensor group, the beam intensity of the linear light source, and the sensitivity of the sensor group.
In an embodiment of the disclosure, the suction force adjustment method of the suction device comprises: communicating wirelessly with a remote control device, transmitting at least one of status information of the suction device and feature information of the object to the remote control device, receiving a suction-force adjustment command from the remote control device, and adjusting the suction force of the suction unit according to the suction-force adjustment command.
In an embodiment of the disclosure, the feature information of the object includes image data of the object, and the remote control device displays an image of the object according to the image data of the object.
Based on the above, in the embodiments of the disclosure, an optical detection unit is disposed on the suction path of the suction pipe, so as to detect objects flowing through the suction pipe, determine the physical features of the object based on the sensing results of the optical detection unit, and regulate the suction force of the suction unit based on the physical features of the objects. In this way, the suction force of the suction device may be adjusted based on the physical features of the object to improve the suction efficiency of the suction device effectively.
The suction unit 106 provides a suction force in the suction channel CH1 to suck objects, such as objects P1 to P3 in this embodiment. In the application scenario where the suction device is a vacuum cleaner, the objects P1 to P3 may be, for example, dust, paper scraps, hair, dander, and liquid, but the disclosure is not limited thereto. The suction unit 106 may be implemented by, for example, a fan motor, but the disclosure is not limited thereto. The optical detection unit is disposed on the suction path D1 of the suction pipe CH1 to detect the objects P1 to P3 flowing through the suction pipe CH1.
Furthermore, the linear light source 102 of the optical detection unit provides a light curtain LC1 formed by a plurality of beams (as shown by the dotted line). The light curtain LC1 is located on the suction path of the objects P1 to P3. The linear light source 102 and the sensor group 104 are disposed on both sides of the suction path D1. The linear light source 102 and the sensor group 104 are, for example, disposed on the suction pipe CH1 (as shown in
The linear light source 102 includes a plurality of light-emitting units LM1 as shown in
The sensor group 104 is disposed on the transmission path of the beams emitted by the linear light source 102. When the beams of the linear light source 102 are not blocked by the objects P1 to P3, the sensor group 104 receives the beams directly from the linear light source 102. Furthermore, the sensor group 104 includes at least one sensor unit SA1. For example, the sensor group 104 includes a plurality of sensor units SA1. The sensor units SA1 are disposed in a straight line at equal intervals corresponding to the linear light sources 102. The sensor group 104 is controlled by the control host 108 to sense periodically and continuously the beams emitted from the linear light source 102 uninterrupted by the objects P1 to P3, and correspondingly generate sensing signals for the control host 108.
The control host 108 determines the physical features of the objects P1 to P3 according to the sensing signals. The physical features of the objects P1 to P3 includes, for example, transparency, quantity, density, shape, size, thickness, etc. Therefore, the control host 108 determines the degree of dirtiness of the environment from the physical features, and regulates the suction force of the suction unit 106 based on the physical features (which indicate the degree of dirtiness of the environment) of the objects P1 to P3. For example, in response to larger or higher quantity, density, shape, size, and/or thickness of the objects P1 to P3 that indicate a higher degree of dirtiness of the environment, the control host 108 increases the suction force of the suction unit 106 to suck the objects P1 to P3; in contrast, in response to a smaller or lower quantity, density, shape, size, and/or thickness of the objects P1 to P3 that indicate a low degree of dirtiness of the environment, the control host 108 may reduce or remain the suction force of the suction unit 106 to suck the objects P1 to P3. In this way, the suction efficiency of the suction device may be improved effectively, and the power consumption may be reduced.
Additionally, in some embodiments, the control host 108 also determines the moving speeds of the objects P1 to P3 according to the sensing signals, and determines according to the moving speeds of the objects P1 to P3 whether the suction force of the suction unit 106 is reduced because it is worn out or other factors, and then according to the moving speeds of the objects P1 to P3 adjusts the suction force of the suction unit 106 to maintain the suction efficiency of the suction device. For example, when the moving speed of the objects P1 to P3 is lower than a preset value, the control host 108 enhances the suction force of the suction unit 106 to increase the moving speed of the objects P1 to P3 to thereby maintain the suction efficiency of the suction device. In addition, the control host 108 may also determine the characteristics of the objects P1 to P3 based on the physical features of the objects P1 to P3. For example, it is determined by the transparency and shape of the objects P1 to P3 whether the objects P1 to P3 are liquid or solid, and the suction force of the suction unit 106 is adjusted accordingly.
In addition, while the control host 108 adjusts the suction force of the suction unit 106, the control host 108 may also adjust the operating parameters of the linear light source 102 and the sensor group 104 according to the suction force of the suction unit 106. For example, when the control host 108 enhances the suction force of the suction unit 106 to increase the moving speeds of the objects P1 to P3, the control host 108 increases the beam intensity of the linear light source 102 and the frequency of enabling the linear light source 102 to emit light (that is, the quantity of the light curtains generated per unit time are increased), and correspondingly increases the sensitivity of the sensor group 104 and the frequency of receiving the beams to ensure that the detection quality of the optical detection unit is not degraded due to the adjustment of the suction force.
Furthermore, when the distances between the objects P1 to P3 passing through the light curtain LC1 and the sensor group 104 and the linear light source 102 are the same--for example, the distance between the objects P1 to P3 and the sensor group 104 is equal to the distance between the objects P1 to P3 and the linear light source 102--the intensity distribution of the sensing signals of the sensor group 104 may represent the light intensity distribution of the beams received by the sensor group 104, and the light intensity distribution of the beams reflects the transparency, quantity, density, shape, size, and thickness of the objects P1 to P3. For example, when the transparency of the objects P1 to P3 is lower, the thickness is thicker, or the height is higher, more beams are interrupted, which in turns weakens the intensity of the sensing signal. The control host 108 may control the sensor group 104 to sense periodically and continuously the beams uninterrupted by the objects P1 to P3 to generate a plurality of sets of sensing signals, and determine the range of the interrupted beams according to the sensing signals. The range where the beams are interrupted reflects the contours of the objects P1 to P3, and the quantity, density, shape, moving speed and size of the objects P1 to P3 may be known. In addition, when the objects P1 to P3 are the same object, the intensity of the sensing signal of the sensor group 104 reflects the distance between the objects P1 to P3 and the linear light source 102. For example, when the objects P1 to P3 are closer to the linear light source 102, the objects P1 to P3 block more beams provided by the linear light source 102, such that the distance between the objects P1 to P3 and the linear light source 102 may be known. Therefore, the control host 108 is able to determine information like transparency, quantity, density, shape, size, moving speed, and thickness of the objects P1 to P3 according to the sensing signals.
In some embodiments, the quantity of the linear light source 102 and the sensor group 104 is not limited to one. For example, in the embodiment of
To sum up, in the embodiment of the disclosure, an optical detection unit is disposed on the suction path of the suction pipe, so as to detect the object flowing through the suction pipe, determine the physical features of the object based on the sensing results of the optical detection unit, and regulate the suction force of the suction unit based on the physical features of the object, such that the suction force of the suction device may be adjusted based on the physical features of the object to improve the suction efficiency of the suction device effectively. In some embodiments, at least one of the status information of the suction device and the feature information of the object is also transmitted to the remote control device, such that the remote user is also able to know the working status of the suction device. In addition, the suction device may also receive a suction-force adjustment command from the remote control device and adjust the suction force accordingly, thereby improving the convenience of the suction device for the users.
| Number | Date | Country | Kind |
|---|---|---|---|
| 110121028 | Jun 2021 | TW | national |
