Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-3, the present application provides a neck massager 10, wherein the neck massager 10 includes a massager body 100, a pressure detecting circuit 200, and a control circuit 300. The pressure detection circuit 200 and the control circuit 300 are disposed on the massage device body 100.
The pressure detection circuit 200 further includes at least a first pressure-sensitive element 210, and the first pressure-sensitive element 210 can be used to detect first pressure information applied by a user. In an alternative scenario, when the user applies pressure to the first pressure-sensitive element 210, the first pressure-sensitive element 210 may detect the pressure to acquire the first pressure information.
The control circuit 300 is electrically connected to the pressure detecting circuit 200, and specifically may be electrically connected to the first pressure-sensitive element 210, so as to obtain first pressure information detected by the first pressure-sensitive element 210, and control the neck massager 10 to be turned on and/or off according to the first pressure information.
In the above embodiment, the first pressure-sensitive element 210 is disposed on the neck massager 10 to detect the first pressure information applied by the user, and the control circuit 300 is used to turn on and/or off the neck massager 10 according to the first pressure information, so that the neck massager 10 can be effectively controlled to be turned on and off without an additional remote controller, thereby saving the cost.
As shown in fig. 1, the massage apparatus body 100 includes a rear neck portion 110, and a first side neck portion 120 and a second side neck portion 130 respectively extending from two ends of the rear neck portion 110. The first pressure sensitive element 210 may then be disposed inside the nape 110.
In an alternative scenario, when the neck massager 10 is worn on the neck of the user, the head of the user leans back to apply a certain pressure to the first pressure-sensitive element 210 located at the back neck 110, and the first pressure-sensitive element 210 detects the pressure and obtains the first pressure information. Subsequently, the control circuit 300 can control the neck massager 10 to be powered on and/or powered off according to the first pressure information.
In the above embodiment, the first pressure-sensitive element 210 is disposed on the inner side of the back neck 110, so that when the user controls the turning on and/or off of the neck massager 10, the user can control the turning on and/or off of the neck massager 10 only by moving the neck to apply corresponding pressure to the first pressure-sensitive element 210, and the problem that the user is inconvenient to operate because the user cannot watch the neck massager 10 when the neck massager 10 is worn on the neck of the user can be solved. And can quickly realize the control of the turning-on and turning-off of the neck massager 10.
In an alternative embodiment, if the first pressure information indicates that the user leans back continuously for a first preset number of times, the neck massager 10 may be controlled to be turned on. Optionally, the first preset number of times may be 3 times, and in order to prevent misoperation, when the first pressure information indicates that the number of times that the user leans backwards continuously is 3 times, the neck massager 10 is controlled to be powered on.
In another alternative embodiment, if the first pressure information indicates that the user leans back continuously for a second preset number of times, the neck massager 10 may be controlled to be turned on. Alternatively, the first preset number of times may be two times, and the neck massager 10 is controlled to be turned off only when the first pressure information indicates that the number of times that the user leans backwards continuously is two times, and in other embodiments, the second preset number of times may be other numbers, which is not limited herein.
The first preset times and the second preset times are different.
As shown in fig. 3, the neck massager 10 includes a massage circuit 400, and the massage circuit 400 is disposed on the massager body 100 for massaging a user. Alternatively, the massage circuit 400 may perform massage to the user by an electrotherapy method, a magnetotherapy method, or the like, which is not particularly limited herein.
As shown in fig. 3, the pressure detecting circuit 200 includes a second pressure-sensitive element 220, the second pressure-sensitive element 220 is disposed inside the first side neck 120, and the second pressure-sensitive element 220 can be used for detecting second pressure information applied by the user. In an optional scenario, when the neck massager 10 is worn on the neck of the user, the head of the user may drive the neck to twist when twisting, and further apply pressure to the second pressure-sensitive element 220 located inside the first side neck 120, and the second pressure-sensitive element 220 may detect the pressure and obtain second pressure information.
The control circuit 300 can be used to obtain the second pressure information and adjust the operating range of the massage circuit 400 according to the second pressure information. Optionally, when the second pressure-sensitive element 220 detects the second pressure information, the control circuit 300 may lower or raise the operating position of the massage circuit 400 according to the second pressure information.
In an alternative scenario, when the neck massager 10 is worn on the neck of the user, the first side neck 120 is close to or fit the neck of the left side of the user, so if the user twists the head to the left, the neck of the left side can apply a certain pressure to the second pressure-sensitive element 220 of the first side neck 120, then the second pressure-sensitive element 220 detects the pressure and obtains second pressure information, and then the control circuit 300 can adjust the operating position of the massage circuit 400 according to the second pressure information.
In another alternative embodiment, the operating range of the neck massager 400 may be increased if the second pressure information indicates that the user has twisted the first lateral neck 120 a third preset number of times. Alternatively, the third preset number of times may be 2 times.
In an alternative embodiment, the operating range of the neck massager 400 may be adjusted downward if the second pressure information indicates that the user has twisted the first lateral neck 120 a seventh predetermined number of times. Alternatively, the seventh preset number may be 3.
As shown in fig. 3, the pressure detecting circuit 200 includes a third pressure-sensitive element 230, the third pressure-sensitive element 230 is disposed inside the second side neck 130, and the third pressure-sensitive element 230 can be used for detecting third pressure information applied by the user. In an optional scenario, when the neck massager 10 is worn on the neck of the user, the head of the user may twist the neck, and further apply pressure to the third pressure-sensitive element 230 located inside the second lateral neck 130, and the third pressure-sensitive element 230 may detect the pressure and obtain third pressure information.
The control circuit 300 may be configured to obtain the third pressure information and lower the operating range of the massage circuit 400 according to the third pressure information. Alternatively, when the third pressure-sensitive element 230 detects the third pressure information, the operating position of the massage circuit 400 may be adjusted downward according to the third pressure information.
In this embodiment, when the pressure detecting circuit 200 includes the third pressure sensitive element 230, the control circuit 300 can be configured to acquire the second pressure information detected by the second pressure sensitive element 220 and adjust the operating range of the massage circuit 400 according to the second pressure information. That is, if the second pressure sensitive element 220 and the third pressure sensitive element 230 are present, the operating range of the massage circuit 400 can be adjusted down based on the third pressure information detected by the third pressure sensitive element 230 alone, and the operating range of the massage circuit 400 can be adjusted up based on the second pressure information detected by the second pressure sensitive element 220 alone. Thereby preventing the occurrence of malfunction.
In an alternative scenario, when the neck massager 10 is worn on the neck of the user, the second lateral neck portion 130 is close to or fits the neck of the right side of the user, so that if the user twists his head to the right, the neck of the right side can apply a certain pressure to the third pressure-sensitive element 230 of the second lateral neck portion 130, and then the third pressure-sensitive element 230 detects the pressure and obtains third pressure information, and then the control circuit 300 can lower the operating position of the massage circuit 400 according to the third pressure information.
In an alternative embodiment, the operating position of the neck massager 400 may be adjusted downward if the third pressure information indicates that the user has twisted the second lateral neck 130 a third predetermined number of times. Alternatively, the fourth preset number may be 2, 3 or other numbers.
In the above embodiment, the second pressure sensing element 220 is arranged to detect the second pressure information applied by the user and the third pressure sensing element 230 is arranged to detect the third pressure information applied by the user, and the massage circuit 400 is turned up according to the second pressure information and the massage circuit 400 is turned down according to the third pressure information, so that the user can control the massage circuit 400 through the neck movement.
In an optional embodiment, the control circuit 300 may be further configured to match a combination of the first pressure information, the second pressure information, and the third pressure information with a preset pressure combination, so as to obtain a twisted degree of the massage apparatus body 100, and further determine whether the twisted degree of the massage apparatus body 100 reaches a threshold, and if the twisted degree reaches the threshold, control the neck massage apparatus 10 to be turned on and/or off.
In an optional scenario, the control circuit 300 matches a combination of the first pressure information, the second pressure information, and the third pressure information with a preset pressure combination. Since the first pressure information, the second pressure information, and the third pressure information all represent the pressure applied by the neck massage apparatus 10, the twisted degree of the massage apparatus body 100 may be further determined from the combination of the first pressure information, the second pressure information, and the third pressure information, and whether the twisted degree reaches the threshold value is determined, and if the twisted degree reaches the threshold value, the neck massage apparatus 10 may be controlled to be turned on and/or off.
In an alternative embodiment, the first pressure sensitive element 210 and/or the second pressure sensitive element 220 and/or the third pressure sensitive element 230 are further used for detecting fourth pressure information applied by the user. In an alternative scenario, when the neck massager 10 is worn on the neck of the user and the head of the user leans back or/and twists, the pressure can be applied to the first pressure-sensitive element 210, the second pressure-sensitive element 220, and/or the third pressure-sensitive element 230, and then the first pressure-sensitive element 210, the second pressure-sensitive element 220, and/or the third pressure-sensitive element 230 detects the pressure and obtains the fourth pressure information.
Subsequently, the control circuit 300 is configured to obtain the fourth pressure information and control the neck massager 10 to power on and/or power off according to the fourth pressure information.
In an alternative scenario, the first pressure sensitive element 210 and the second pressure sensitive element 220 cooperate to detect fourth pressure information applied by the user. That is, the information of the user's head leaning backward and head twisting to the left can be obtained. Alternatively, if the fourth pressure information indicates that the head of the user continuously leans backward for a fifth preset number of times and then twists to the left for a sixth preset number of times, the neck massager 10 may be controlled to be turned on. If the first pressure information indicates that the head of the user is twisted to the left for a sixth preset number of times and then leans back for a fifth preset number of times, the neck massager 10 may be controlled to turn off, i.e. the fourth pressure information not only includes the detected pressures of the first pressure sensitive element 210, the second pressure sensitive element 220 and/or the third pressure sensitive element 230, but also includes the sequence of the detected pressures.
In another alternative scenario, it is also possible that the first pressure sensitive element 210 and the second pressure sensitive element 220 and the third pressure sensitive element 230 cooperate to detect fourth pressure information applied by the user. Or the second pressure-sensitive element 220 and the third pressure-sensitive element 230 cooperate to detect the fourth pressure information applied by the user, which is not limited herein.
In the above embodiment, the fourth pressure information is acquired by combining the first pressure-sensitive element 210, the second pressure-sensitive element 220 and/or the third pressure-sensitive element 230, and the on/off of the neck massage apparatus 10 is controlled according to the fourth pressure information, so that the misoperation can be further prevented, and the on/off of the neck massage apparatus 10 can be controlled through more complicated neck actions.
As shown in fig. 3, the neck massager 10 includes a language collecting circuit 500, which is disposed on the massager body 100 and electrically connected to the control circuit 300, and is used for collecting language information of a user; the control circuit 300 is used for acquiring the language information and adjusting the working gear of the massage circuit 400 according to the language information.
In an optional scenario, the language information of the user may be collected by the language collection circuit 500, for example, the user may wake up the language collection circuit 500 by a "small moxa" or other language instruction, and then the language collection circuit 500 collects the language information of the user, such as "small moxa," adjusting the working position of the massage circuit, "and so on, so that the control circuit 300 may adjust the working position of the massage circuit 400 according to the language information, and in other embodiments, the neck massage apparatus 10 may also be controlled by a similar or same semantic language to adjust the working position of the massage circuit 400.
In summary, the present application provides a neck massager 10, which detects first pressure information applied by a user by providing a first pressure-sensitive element 210 on the neck massager 10, and turns on and/or off the neck massager 10 by using a control circuit 300 according to the first pressure information, so as to effectively control the turning on and off of the neck massager 10 without an additional remote controller, thereby saving cost. Furthermore, by disposing the first pressure-sensitive element 210 on the inner side of the back neck portion 110, when the user controls the turning on and/or turning off of the neck portion massage apparatus 10, the user only needs to move the neck portion to apply corresponding pressure to the first pressure-sensitive element 210, so as to control the turning on and/or turning off of the neck portion massage apparatus 10, and thus, the problem that the user is inconvenient to operate because the user cannot watch the neck portion massage apparatus 10 when the user wears the neck portion massage apparatus 10 on the neck portion of the user can be solved. And can quickly realize the control of the turning-on and turning-off of the neck massager 10. Furthermore, the fourth pressure information is obtained by combining the first pressure-sensitive element 210, the second pressure-sensitive element 220 and/or the third pressure-sensitive element 230, and the neck massage apparatus 10 is controlled to be turned on and/or off according to the fourth pressure information, so that the misoperation can be further prevented, and the turning on and/or off of the neck massage apparatus 10 can be controlled through more complicated neck actions.
Referring to fig. 4, fig. 4 is a flowchart of a control method of a neck massager according to a first embodiment of the present application, the method being applied to the neck massager in any one of the above embodiments, the method including the following steps:
and S11, the neck massage apparatus detects first pressure information applied by the user by using the first pressure-sensitive element of the pressure detection circuit.
The neck massager detects first pressure information applied by a user by using a first pressure sensitive element in a pressure detection circuit.
And S12, the neck massage instrument obtains the first pressure information by using the control circuit electrically connected with the pressure detection circuit and controls the neck massage instrument to be turned on and/or turned off according to the first pressure information.
Then, the neck massage instrument obtains first pressure information by using a control circuit electrically connected with the pressure detection circuit, and further controls the neck massage instrument to be turned on and/or turned off according to the first pressure information.
Wherein, the neck massager also comprises a massager body, and the pressure detection circuit and the control circuit are both arranged on the massager body.
The massage instrument body comprises a back neck part, a first side neck part and a second side neck part, wherein the first side neck part and the second side neck part respectively extend from two ends of the back neck part; the first pressure sensitive element is disposed inside the rear neck portion.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the embodiments, and are not described again.
Referring to fig. 5, fig. 5 is a schematic flowchart illustrating the sub-step of step S12 in fig. 4, which specifically includes the following steps:
and S121, if the first pressure information shows that the continuous backward tilting times of the user are the first preset times, the neck massage instrument utilizes the control circuit to control the neck massage instrument to be started.
Optionally, if the first pressure information indicates that the number of times that the user leans backwards continuously is a first preset number of times, the neck massager utilizes the control circuit to control the neck massager to start.
And S122, if the first pressure information shows that the continuous backward leaning times of the user are the second preset times, the neck massager controls the neck massager to be turned off by using the control circuit.
Optionally, if the first pressure information indicates that the number of times that the user leans backwards continuously is a second preset number, the neck massager controls the neck massager to turn off by using the control circuit.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the embodiments, and are not described again.
In an optional embodiment, the neck massager also utilizes the massage circuit arranged on the massager body to massage the user.
Referring to fig. 6, fig. 6 is a flowchart illustrating a control method of a neck massager according to a second embodiment of the present disclosure. The method comprises the following steps:
and S21, the neck massage apparatus detects second pressure information applied by the user by using the second pressure-sensitive element of the pressure detection circuit.
Optionally, the neck massager detects second pressure information applied by the user by using a second pressure sensitive element of the pressure detection circuit.
And S22, the neck massage instrument acquires the second pressure information by using the control circuit and adjusts the working gear of the massage circuit according to the second pressure information.
And then the neck massager acquires second pressure information by using the control circuit and adjusts the working gear of the massage circuit according to the second pressure information.
Wherein the second pressure sensitive element is arranged at the inner side of the first side neck part.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the above embodiments, and are not described again here.
Referring to fig. 7, fig. 7 is a flowchart illustrating a control method of a neck massager according to a third embodiment of the present disclosure. The method comprises the following steps:
and S31, the neck massage apparatus detects third pressure information applied by the user by using the third pressure sensitive element of the pressure detection circuit.
Optionally, the neck massager may further detect third pressure information applied by the user using a third pressure sensitive element of the pressure detection circuit.
S32, the neck massager obtains third pressure information by using the control circuit and lowers the working gear of the massage circuit according to the third pressure information;
and then the neck massage instrument obtains third pressure information by using the control circuit and according to the third pressure information.
And S33, the neck massage instrument acquires the second pressure information by using the control circuit and increases the working gear of the massage circuit according to the second pressure information.
And then the neck massage instrument acquires second pressure information by using the control circuit and increases the working gear of the massage circuit according to the second pressure information.
Wherein the third pressure sensitive element is arranged inside the second lateral neck part.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the above embodiments, and are not described again here.
Referring to fig. 8, fig. 8 is a flowchart illustrating a control method of a neck massager according to a fourth embodiment of the present disclosure. The method comprises the following steps:
and S41, the neck massage instrument utilizes the control circuit to match the combination of the first pressure information, the second pressure information and the third pressure information with the preset pressure combination to obtain the twisting degree of the massage instrument body.
Optionally, the neck massager may further match a combination of the first pressure information, the second pressure information, and the third pressure information with a preset pressure combination by using the control circuit, so as to obtain a degree of torsion of the case source body.
And S42, judging whether the torsion degree reaches a threshold value. And judging whether the torsion degree reaches a threshold value.
And S43, if the threshold value is reached, controlling the neck massage device to be turned on and/or off.
If the threshold value is reached, the neck massage instrument can be controlled to be switched on and/or switched off.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the above embodiments, and are not described again here.
Referring to fig. 9, fig. 9 is a flowchart illustrating a control method of a neck massager according to a fifth embodiment of the present application. The method comprises the following steps:
and S51, the neck massager collects the language information of the user by using a language collecting circuit which is arranged on the massager body and is electrically connected with the control circuit.
Optionally, the neck massager may further collect the language information of the user by using a language collecting circuit disposed on the massager body and electrically connected to the control circuit.
And S52, the neck massage instrument acquires the language information by using the control circuit and adjusts the working gear of the massage circuit according to the language information.
Then, the neck massager further utilizes the control circuit to obtain language information, and adjusts the working gear of the massage circuit according to the language information.
The detailed structure and the detailed steps of the neck massager for realizing the steps are described in detail in the embodiments, and are not described again.
The logical processes of the above-described control method are presented as a computer program, which can be stored in a computer storage medium if it is sold or used as a stand-alone software product, and thus the present invention proposes a computer storage medium. Referring to fig. 10, fig. 10 is a schematic structural diagram of an embodiment of a computer storage medium 700 according to the present invention, in which a computer program 71 is stored, and the computer program is executed by a processor to implement the distribution network method or the control method.
The computer storage medium 700 may be a medium that can store a computer program, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk, or may be a server that stores the computer program, and the server may send the stored computer program to another device for running or may run the stored computer program by itself. The computer storage medium 700 may be a combination of multiple entities from a physical point of view, for example, multiple servers, servers plus storage, or storage plus removable hard disks.
The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes performed by the present specification and the attached drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.