Patent Description:
The dual-probe ultrasonic device is a medical device manufactured based on the principle of ultrasound, which is used in conjunction with an ultrasonic machine and is configured to transmit and receive ultrasonic waves during the ultrasonic detection process. A dual-probe wireless ultrasonic device usually includes two probes. The types of the two probes can be the same or different. The type of the probe includes, for example, a linear array probe, an arc array probe, and a phased array probe.

The dual-probe ultrasonic device includes: two sets of ultrasonic probes provided on a probe body and having different installation positions, a control board respectively connected to the two sets of ultrasonic probes and provided inside the probe body, and a communication device for transmitting images.

In the prior art, a USB cable is usually connected to the outside of the probe body to connect with an external communication device for image transmission. With the increase in user demands, the demand for dual-probe wireless ultrasonic devices has become more widespread. In this device, the communication device is an antenna which can transmit wireless signals to communicate with external devices and then transmit images.

For the dual-probe wireless ultrasonic device, there are mainly two manners to install the antenna in the prior art. One is to install the antenna on an ultrasonic probe side. This installation manner is subject to requirements of synchronization signal transmission of the ultrasonic probe. The installation of the antenna on the ultrasonic probe side may affect the image quality. The other manner is to install the antenna on a main body housing. For this solution of installing the antenna on the main body housing, if the user holds the probe body during use, the antenna signal transmission is also affected.

The document <CIT> discloses a multi-headed imaging probe and an imaging system using the same. Specifically provided is the diagnostic imaging system that includes an image acquisition component, a transmitter operatively coupled to the image acquisition component to transmit a signal therefrom, and a beamformer operatively coupled to the image acquisition component to receive image data therefrom. Also included is a processor configured to assemble images from the acquired image data and a display configured to display the images. The image acquisition component includes a multi-headed probe that has a plurality of transducers configured to permit a change of active transducers during an imaging session without a change of the image acquisition component.

The document <CIT> discloses a wireless ultrasound probe having a probe case enclosing a transducer array, a probe controller, and a transceiver which wirelessly receives control signals from and transmits image signals to a host system. Mounted on the probe case is a liquid-tight user interface including basic probe user controls such as directional controls, an image freeze control, and an image save control. The user interface may be fabricated as a touch panel LCD or OLED display. The probe may alternatively be controlled by a separate user interface which wirelessly transmits control signals to the host system or the probe. Either user interface may also include a display such as battery charge and signal strength indicators.

The present application provides a dual-probe wireless ultrasonic device, a control method and a control system thereof.

In order to achieve the above application purposes, a dual-probe wireless ultrasonic device is provided in an embodiment of the present application, including: two sets of ultrasonic probes arranged on a probe body and having different installation positions, and a control board communicatively connected with the two sets of ultrasonic probes respectively and arranged inside the probe body;.

the dual-probe wireless ultrasonic device further includes: two sets of antennas for data transmission and communicatively connected with the control board;.

the two sets of ultrasonic probes comprise: a first ultrasonic probe and a second ultrasonic probe;.

the two sets of antennas comprising: a first antenna arranged on the second ultrasonic probe and communicatively connected with the first ultrasonic probe, and a second antenna arranged on the first ultrasonic probe and communicatively connected with the second ultrasonic probe.

As an improvement of an embodiment of the present application, a material of the probe body is a metal material and/or a plastic material.

As an improvement of an embodiment of the present application, the two sets of ultrasonic probes are respectively arranged at two opposite end portions of the probe body.

As an improvement of an embodiment of the present application, at least one of the two sets of antennas is arranged away from the probe body.

As an improvement of an embodiment of the present application, each ultrasonic probe includes: a housing configured to receive a functional component of the ultrasonic probe, and at least one of the two sets of antennas is arranged adjacent to an inner wall surface of the housing.

As an improvement of an embodiment of the present application, at least one of the two sets of antennas is arranged on the inner wall surface of the housing.

As an improvement of an embodiment of the present application, at least one of the two sets of antennas is glued and fixed on the inner wall surface of the housing, or fixed on the inner wall surface of the housing in a snap-fit manner.

As an improvement of an embodiment of the present application, the dual-probe wireless ultrasonic device further includes: a battery arranged inside the probe body.

In order to achieve the above invention purposes, a method for controlling a dual-probe wireless ultrasonic device of the above embodiment is provided in an embodiment of the present application, including:.

In order to achieve the above invention purposes, a system for controlling a dual-probe wireless ultrasonic device of the above embodiment is provided in an embodiment of the present application, including:.

Compared to the prior art, the present application has the beneficial effects that: the dual-probe wireless ultrasonic device of the present application can wirelessly support the operation of dual-acoustic probes, and when any probe operates, the transmission of the probe signal is not interfered, thereby achieving an image with a better quality.

The present application will be described in detail with reference to specific embodiments shown in accompanying drawings. However, these embodiments do not limit the present application; and transformations in the structure, method, or function made by those skilled in the art based on these embodiments are all included in the protection scope of the present application.

Referring to <FIG>, a dual-probe wireless ultrasonic device is provided in an embodiment of the present application, which includes: two sets of ultrasonic probes provided on a probe body <NUM> and having different installation positions, a control board <NUM> respectively communicatively connected with the two sets of ultrasonic probes and provided inside the probe body <NUM>, and two sets of antennas for a data transmission and communicatively connected with the control board <NUM>. The ultrasonic probes include a first ultrasonic probe <NUM> and a second ultrasonic probe <NUM> provided at different positions on the probe body <NUM>. The antennas include: a first antenna <NUM> provided on the second ultrasonic probe <NUM> and communicatively connected with the first ultrasonic probe <NUM>, and a second antenna <NUM> provided on the first ultrasonic probe <NUM> and communicatively connected with the second ultrasonic probe <NUM>.

It should be noted that the types of the first ultrasonic probe <NUM> and the second ultrasonic probe <NUM> can be the same or different, which can be both one of a linear array probe, an arc array probe, and a phased array probe. In a specific implementation of the present application, the first ultrasonic probe <NUM> is an arc array probe, and the second ultrasonic probe <NUM> is a phased array probe.

In an embodiment of the present application, since the antenna is provided by avoiding the probe body <NUM>, a material of the probe body <NUM> does not need to be limited, which can be, for example, ABS, PC, plastic, metal, etc. In a preferred embodiment of the present application, the material of the probe body <NUM> is a metal material and/or a plastic material. Therefore, when the dual-probe wireless ultrasonic device has a requirement to ground, and the material of the probe body <NUM> is set to the metal or electroplating within a plastic housing, etc., without screening the transmission of the antenna signal.

Correspondingly, in a preferred embodiment of the present application, the material of the probe body <NUM> is the metal material. In such a manner, while meeting the requirement of grounding the dual-probe wireless ultrasonic device, the product can be made lighter and thinner, and has a certain texture. Further, the transmission of the antenna signal is not affected either.

In embodiments of the present application, the positions of the two probes are not specifically limited. For example, the two ultrasonic probes are arranged at an acute angle, a right angle, or an obtuse angle between them. In a preferred embodiment of the present application, the two sets of ultrasonic probes are respectively arranged at two opposite end portions of the probe body <NUM>.

In embodiments of the present application, the installation position of any set of antennas corresponding to the ultrasonic probe can be freely selected, for example, can be arranged on the outside and/or inside of the ultrasonic probe.

It should be appreciated that, for each ultrasonic probe, the farther away the antenna communicatively connected with the ultrasonic probe, the better the communication effect. In a preferred embodiment of the present application, the two sets of antennas are arranged away from the probe body <NUM>, to increase a distance between the corresponding ultrasonic probe and the antenna as far as possible to ensure the communication effect.

In a preferred implementation of the present application, the first ultrasonic probe <NUM> includes a housing <NUM> configured to receive a functional component of the first ultrasonic probe; the second ultrasonic probe <NUM> includes a housing <NUM> configured to receive a functional component of the second ultrasonic probe; the materials of the housings (<NUM>, <NUM>) are all plastic materials. Preferably, the two sets of antennas can be selectively arranged inside the corresponding ultrasonic probes respectively. The functional component is, for example, a transducer, etc., which is not described in detail here.

In an embodiment of the present application, the two sets of antennas (<NUM>, <NUM>) can be selectively arranged adjacent to inner wall surfaces of the corresponding housings (<NUM>, <NUM>) respectively.

In a further embodiment of the present application, the two sets of antennas (<NUM>, <NUM>) can be selectively arranged on the inner wall surfaces of the corresponding housings (<NUM>, <NUM>) respectively.

In a specific embodiment of the present application, the two sets of antennas (<NUM>, <NUM>) can be fixed on the inner wall surfaces of the corresponding housings (<NUM>, <NUM>) respectively in a variety of ways, for example, can be glued and fixed on the inner wall surfaces of the housings respectively, or fixed on the inner wall surfaces of the housings respectively in a snap-fit manner, which will not be described in detail here.

In a specific embodiment of the present application, the first antenna <NUM> is glued and fixed on the inner wall surface of the housing <NUM> of the second ultrasonic probe <NUM>, and is arranged adjacent to the housing <NUM> and away from the end portion of the probe body <NUM>. The second antenna is glued and fixed on the inner wall surface of the housing <NUM> of the first ultrasonic probe <NUM>, and is arranged adjacent to the housing <NUM> and away from the end portion of the probe body <NUM>.

In addition, in a preferred embodiment of the present application, the first antenna <NUM> and the second antenna <NUM> are both communicatively connected with the control board <NUM> through a cable, and the control board <NUM> controls the conductions of the two sets of antennas during the operation of the dual-probe wireless ultrasonic device. The specific conduction process will be described in detail below.

In a preferred embodiment of the present application, the dual-probe wireless ultrasonic device further includes: a battery <NUM> arranged inside the probe body. The battery <NUM> is configured to provide power to the entire device to satisfy various application scenarios, which will not be detailed here.

As shown in <FIG>, in an embodiment of the present application, a method for controlling a dual-probe wireless ultrasonic device as described above is provided. The method includes: if the first ultrasonic probe is monitored and activated, the first antenna is turned on while the second antenna is turned off; if the second ultrasonic probe is monitored and activated, the second antenna is turned on while the first antenna is turned off; the first antenna is arranged on the second ultrasonic probe, and the second antenna is arranged on the first ultrasonic probe. In this way, when the first ultrasonic probe operates, the second antenna arranged thereon is automatically turned off, and the first antenna which is away from the first ultrasonic probe and is arranged on the second ultrasonic probe is activated; when the second ultrasonic probe operates, the first antenna arranged thereon is automatically turned off, and the second antenna which is away from the second ultrasonic probe and is arranged on the first ultrasonic probe is activated; thus, it can be ensured that each ultrasonic probe is not interfered by a signal from the antenna arranged thereon when operating; at the same time, because the antenna is arranged on the ultrasonic probe, the user can also hold any position on the probe body when using the wireless ultrasonic device, which is convenient for the user to operate.

As shown in <FIG>, the present application also provides a system for controlling a dual-probe wireless ultrasonic device as described above, the system includes: an operation state monitoring module <NUM> and a control conversion module <NUM>. The working status monitoring module <NUM> is configured to monitor a currently activated ultrasonic probe in real time after the dual-probe wireless ultrasonic device is turned on. The control conversion module <NUM> is configured to control turn-on of the antenna through the activated ultrasonic probe; if the first ultrasonic probe is monitored and activated, the first antenna is turned on while the second antenna is turned off; if the second ultrasonic probe is monitored and activated, the second antenna is turned on while the first antenna is turned off. The first antenna is arranged on the second ultrasonic probe, and the second antenna is arranged on the first ultrasonic probe.

In conclusion, the dual-probe wireless ultrasonic device in the present application can wirelessly support dual-acoustic probe operation; and when any probe operates, the transmission of the probe signal is not interfered, thereby obtaining images with a higher quality.

It should be understood that although this specification is described in accordance with the embodiments, not each embodiment only includes one independent technical solution. This narration mode in the specification is merely for clarity, and those skilled in the art should regard the specification as a whole. The technical solutions in the embodiments can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claim 1:
A dual-probe wireless ultrasonic device, comprising: two sets of ultrasonic probes arranged on a probe body (<NUM>) and having different installation positions, and a control board (<NUM>) communicatively connected with the two sets of ultrasonic probes respectively and arranged inside the probe body (<NUM>);
wherein the dual-probe wireless ultrasonic device further comprises: two sets of antennas for data transmission and communicatively connected with the control board;
wherein, the two sets of ultrasonic probes comprise: a first ultrasonic probe (<NUM>) and a second ultrasonic probe (<NUM>);
the two sets of antennas comprising: a first antenna (<NUM>) arranged on the second ultrasonic probe (<NUM>) and communicatively connected with the first ultrasonic probe (<NUM>), and a second antenna (<NUM>) arranged on the first ultrasonic probe (<NUM>) and communicatively connected with the second ultrasonic probe (<NUM>).