CN213696988U - Modular portable supersound bone densimeter - Google Patents

Abstract

The utility model discloses a modularized portable ultrasonic bone densitometer, which comprises a casing, wherein a processor, an ultrasonic signal controller, a memory and a display screen are arranged in the casing and are controlled by electric signals of the processor; the ultrasonic signal controller is provided with an ultrasonic probe for detecting the bone density in an electrical signal connection way. The whole device is designed in a portable shell, the device is also provided with a power switch, a battery and other conventional designs, and the battery is used for providing power for the whole bone densitometer; the power switch is used for turning on, restarting or turning off the bone densitometer. Wherein the processor is configured to provide information processing, computing, and control capabilities; the ultrasonic signal controller is used for controlling the amplitude, frequency, phase and the like of the ultrasonic signal; the ultrasonic probe sends specific sound wave signals to the human body and can receive the signals, and the ultrasonic signal controller can control the ultrasonic probe to send sound waves with different parameters to the human body. The utility model discloses it is portable to be applicable to basic unit's hospital and family user self-test.

Description

Modular portable supersound bone densimeter

Technical Field

The utility model belongs to medical treatment check out test set field, concretely relates to portable supersound bone densimeter of modular.

Background

Osteoporosis has become an important health problem for the middle-aged and elderly people in our country. The national health committee published the first Chinese osteoporosis epidemiological survey result in 2018, and the survey shows that: the prevalence rate of osteoporosis of people over 50 years old is 19.2%. The osteoporosis problem of middle-aged and old women is particularly serious, and the osteoporosis prevalence rate of women over 65 years old reaches 51.6 percent. The investigation also finds that the population with low bone mass in China is huge, the low bone mass rate of the population of 40-49 years old is 32.9%, the low bone mass rate of the population of more than 50 years old reaches 46.4%, and the population is a high-risk population for osteoporosis. The cognition of residents on osteoporosis is generally insufficient, and the bone density detection rate needs to be improved urgently.

The quantitative ultrasonic diagnosis scheme has the advantages of low price, no radiation and the like, so that the quantitative ultrasonic diagnosis scheme becomes an important means for screening and risk assessment of osteoporosis risk groups. On one hand, the ultrasonic bone mineral density equipment used in the current medical institution transmits detection signals through wires, so that the use radius of the equipment is limited by the length of a data wire, and the detection is inconvenient; on the other hand, the ultrasonic bone densitometer used in the current medical institution has many components, large equipment volume and complex operation, is not convenient for hospital medical care personnel to operate and use, and is not beneficial to popularization and use of the basic health medical institution and family users.

Disclosure of Invention

The utility model aims to solve the technical problem to the current situation of above-mentioned prior art, and provide equipment fixing easy and simple to handle, can pass through wireless communication technology transmission detection data, be applicable to the portable supersound bone densimeter of a modular of basic unit hospital and family.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: a modularized portable ultrasonic bone densitometer comprises a shell, wherein a processor, an ultrasonic signal controller, a memory and a display screen are arranged in the shell, and the ultrasonic signal controller, the memory and the display screen are controlled by electric signals of the processor; the ultrasonic signal controller is provided with an ultrasonic probe for detecting the bone density in an electrical signal connection way.

In order to optimize the technical scheme, the adopted measures further comprise:

the shell comprises a sub-shell and a main shell which are connected through a snap fastener, and the ultrasonic signal controller and the ultrasonic probe are arranged in the sub-shell; the processor and the memory are arranged in the female shell, and the display screen is arranged outside the female shell.

The sub-shell is provided with an acoustic lens for isolating the ultrasonic probe from the outside.

The sub-shell is provided with a sub-interface which is connected with the ultrasonic probe through an electric signal, and the main shell is provided with a main interface of an electric signal processor; the sub-interface and the mother interface are electric signal plug-in structures.

The sub-shell is provided with a clamping groove, the female shell is provided with a clamping protrusion matched with the clamping groove in a clamping mode, the sub-interface is located in the clamping groove, and the female interface is located on the clamping protrusion.

The electric signal connection of the processor is provided with a loudspeaker and a wireless communication module, and the loudspeaker and the wireless communication module are arranged in the female shell.

The above-mentioned mother shell also has USB interface for exporting data from the memorizer.

The above described female housing is also provided with sensors for monitoring environmental data as a reference.

The display screen is a touch display screen.

Compared with the prior art, the utility model discloses a portable supersound bone density appearance of modularization, including the casing, be equipped with the treater in the casing to and through the supersound signal controller, memory, the display screen of treater electric signal control; the ultrasonic signal controller is provided with an ultrasonic probe for detecting the bone density in an electrical signal connection way. The whole device is designed in a portable shell, the device is also provided with a power switch, a battery and other conventional designs, and the battery is used for providing power for the whole bone densitometer; the power switch is used for turning on, restarting or turning off the bone densitometer. Wherein the processor is configured to provide information processing, computing, and control capabilities; the ultrasonic signal controller is used for controlling the amplitude, frequency, phase and the like of the ultrasonic signal; the ultrasonic probe sends specific sound wave signals to the human body and can receive the signals, and the ultrasonic signal controller can control the ultrasonic probe to send sound waves with different parameters to the human body. The utility model discloses it is portable to be applicable to basic unit's hospital and family user self-test.

Drawings

FIG. 1 is a schematic diagram of the processor controlling modules of the present invention;

FIG. 2 is a schematic perspective view of the present invention;

FIG. 3 is an exploded schematic view of FIG. 2;

fig. 4 is an exploded view from another perspective.

Detailed Description

Embodiments of the present invention are described in further detail below with reference to the accompanying drawings.

Wherein the reference numerals are: the ultrasonic diagnostic device comprises a processor 1, a loudspeaker 2, a battery 3, a power switch 4, a USB interface 5, an ultrasonic signal controller 6, an ultrasonic probe 7, a memory 8, a display screen 9, a wireless communication module 10, a sensor 11, a shell 12, a female shell 121, a sub-shell 122, a female interface 131, a sub-interface 132, a clamping convex 141, a clamping groove 142 and an acoustic lens 16.

Fig. 1 to 4 are schematic structural views of the present invention, as shown in fig. 1, the present invention relates to a portable modular ultrasonic bone densitometer, which comprises a casing 12, a processor 1 is arranged in the casing 12, and an ultrasonic signal controller 6, a memory 8 and a display screen 9 controlled by an electric signal of the processor 1; the ultrasonic signal controller 6 is connected with an electric signal and provided with an ultrasonic probe 7 for detecting the bone density. The whole device is designed in a portable housing 12, the device also has a conventional design of a power switch 4, a battery 3 and the like, the battery 3 is used for supplying power for the whole bone densitometer, and the power switch 4 is used for starting, restarting or turning off the bone densitometer. Wherein the processor 1 is used to provide information processing, computing and control capabilities;

the ultrasonic signal controller 6 is used for controlling the amplitude, frequency, phase and the like of the ultrasonic signal; the ultrasonic probe 7 sends a specific sound wave signal to the human body and can receive the signal;

the Memory 8 is used for storing data, programs, instruction codes and the like, and the Memory 8 is a non-volatile storage medium such as a Read-Only Memory (ROM) or a Random-Access-Memory (RAM);

the display screen 9 is used for displaying the interaction interface of the bone densitometer;

in an embodiment, as shown in fig. 2 to 4, the casing 12 includes a sub-casing 122 and a main casing 121 that are snap-fit connected, and the ultrasonic signal controller 6 and the ultrasonic probe 7 are disposed in the sub-casing 122; the processor 1 and the memory 8 are provided in the main casing 121, and the display screen 9 is provided outside the main casing 121. In the present apparatus, the sub-housing 122 with the ultrasonic signal controller 6 and the ultrasonic probe 7 is equivalent to a detachable and replaceable probe, and the sub-housing 122 and the female housing 121 are connected by such a physical snap-fit manner, so that the sub-housing 122 as a probe can be conveniently replaced.

In the embodiment, as shown in fig. 2 and 3, the sub-housing 122 is provided with an acoustic lens 16 for isolating the ultrasonic probe 7 from the outside, and the acoustic lens 16 is in direct contact with the skin of the human body.

In an embodiment, as shown in fig. 4, the sub-housing 122 is provided with a sub-interface 132 electrically connected to the ultrasonic signal controller 6, and as shown in fig. 3, the main housing 121 is provided with a main interface 131 of the electrical signal processor 1; the sub-interface 132 and the mother interface 131 are electrical signal plug-in structures, and the plug-in arrangement of the sub-interface 132 and the mother interface 131 enables the sub-housing 122 to complete the on-off of a circuit through plugging, so that different sub-housings 122 can be combined with the mother housing 121 in a plug-in manner to transmit data signals.

In an embodiment, as shown in fig. 4, a card slot 142 is disposed on the sub-housing 122, as shown in fig. 3, a card protrusion 141 engaged with the card slot 142 is disposed on the main housing 121, the sub-interface 132 is disposed in the card slot 142, and the main interface 131 is disposed on the card protrusion 141. The engagement between the protrusion 141 and the slot 142 not only positions the sub-connector 132 and the female connector 131, but also prevents the sub-housing 122 from shaking to damage the sub-connector 132 and the female connector 131.

In the embodiment, as shown in fig. 1, the processor 1 is electrically connected to the speaker 2 and the wireless communication module 10, and the speaker 2 and the wireless communication module 10 are disposed in the female housing 121.

The wireless communication module 10 is used for receiving and transmitting various data, and is one or more wireless communication technologies such as wifi (wireless fidelity), BlueTooth (BlueTooth), rfid (radio Frequency identification), and 5G;

in the embodiment, as shown in fig. 1 and 4, the female housing 121 is further provided with a USB interface 5 for exporting data from the memory 8.

In an embodiment, as shown in fig. 1, the female housing 121 is further provided with a sensor 11 for monitoring environmental data as a reference. The sensor 11 is used for detecting and collecting information data related to a user, an environment and an instrument, and can replace and select other sensors such as an optical sensor, a distance sensor, an acceleration sensor, a pressure sensor, a gyroscope, a barometer, a hygrometer, a thermometer and an infrared sensor.

In the embodiment, the display screen 9 is a touch display screen.

While the preferred embodiments of the present invention have been illustrated, various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention.

Claims (9)

1. A portable ultrasonic bone densitometer of modular design, comprising a housing (12), characterized by: the shell (12) is internally provided with a processor (1), an ultrasonic signal controller (6) controlled by an electric signal of the processor (1), a memory (8) and a display screen (9); the ultrasonic signal controller (6) is provided with an ultrasonic probe (7) for detecting the bone density in an electric signal connection way.

2. The modular portable ultrasonic bone densitometer of claim 1, wherein: the shell (12) comprises a sub shell (122) and a main shell (121) which are connected through snap fasteners, and the ultrasonic signal controller (6) and the ultrasonic probe (7) are arranged in the sub shell (122); the processor (1) and the memory (8) are arranged in the female shell (121), and the display screen (9) is arranged outside the female shell (121).

3. The modular portable ultrasonic bone densitometer of claim 2, wherein: the sub-shell (122) is provided with an acoustic lens (16) for isolating the ultrasonic probe (7) from the outside.

4. The modular portable ultrasonic bone densitometer of claim 3, wherein: the sub-shell (122) is provided with a sub-interface (132) which is electrically connected with the ultrasonic signal controller (6), and the main shell (121) is provided with a main interface (131) of the electric signal processor (1); the sub-interface (132) and the mother interface (131) are electric signal plug-in structures.

5. The modular portable ultrasonic bone densitometer of claim 4, wherein: the improved shell is characterized in that a clamping groove (142) is formed in the sub-shell (122), a clamping protrusion (141) matched with the clamping groove (142) in a clamping mode is arranged on the female shell (121), the sub-interface (132) is located in the clamping groove (142), and the female interface (131) is located on the clamping protrusion (141).

6. The modular portable ultrasonic bone densitometer of claim 5, wherein: the processor (1) is electrically connected with a loudspeaker (2) and a wireless communication module (10), and the loudspeaker (2) and the wireless communication module (10) are arranged in the female shell (121).

7. The modular portable ultrasonic bone densitometer of claim 6, wherein: the female shell (121) is also provided with a USB interface (5) for exporting data from the memory (8).

8. The modular portable ultrasonic bone densitometer of claim 7, wherein: the female housing (121) is also provided with a sensor (11) for monitoring environmental data as a reference.

9. The portable modular ultrasonic bone densitometer of any one of claims 1 to 8, wherein: the display screen (9) is a touch display screen.

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