RU193007U1 - Device for attaching an ultrasonic sensor to a human body - Google Patents

Abstract

The utility model relates to medicine, namely to devices that attach ultrasound sensors to the patient’s body during ultrasound examinations, and can be used for ultrasound examinations of peripheral, brachiocephalic, and transcranial vessels. It simplifies the design of the device, which provides a simple and reliable angular positioning of the ultrasonic sensor with the fixation of the selected position. The device includes a sphere-shaped sleeve 1, a housing 2 and a fixing cover 3. The sphere-shaped sleeve 1 is made in the form of a spring split sleeve, the outer surface of which has the shape of a sphere truncated by two parallel planes. Its internal structural implementation provides the possibility of placing an ultrasonic sensor in it. The housing 2 has a working surface 4, made with the possibility of attachment to the human body. A through channel 5 is made in the housing 2. A sphere-shaped sleeve 1 is installed in the through channel 5 of the housing 2 with the exception of the possibility of its falling out from the side of the working surface 4. On the side opposite to the working surface, the fixing cover 3 is installed on the housing 2. The fixing cover 3 has a through hole 6, coaxial with the through channel 5 of the housing 2.5. f-ly, 1 il.

Description

The utility model relates to medicine, namely to devices that attach ultrasound sensors to the patient’s body during ultrasound examinations for a long time interval, and can be used for ultrasound examinations of peripheral, brachiocephalic, and transcranial vessels.

Transcranial Doppler studies of cerebral circulation are, in a number of cases, key tests in monitoring the condition of patients in the treatment of vascular pathologies, during early rehabilitation of patients with acute cerebrovascular accident (stroke), during functional tests, and assessing the vascular reserve of the body and other.

The appearance of the first portable digital Doppler systems for transcranial monitoring has significantly expanded the area of application of these devices, allowing the specified diagnostics to be carried out autonomously. However, existing devices for attaching ultrasonic sensors, such as head helmets for transcranial dopplerography, are rather cumbersome and their use is almost impossible for long-term use due to pain sensations experienced by patients. In addition, there are significant design restrictions on the placement of ultrasonic sensors.

A prior art device is known for attaching an ultrasonic sensor to a human body, including a spherical adapter mounted with the possibility of its angular positioning and made with the possibility of placing an ultrasonic sensor in it (see, for example, RU 2663646 C2, publ. 07.08.2018 )

The disadvantage of this device is its bulkiness. The design of the holder determines that the patient is examined exclusively in the supine position and only for a specific area on the surface of the patient’s body. The complexity of the design requires certain skills from medical personnel when installing sensors using the holder in question, which limits the possibility of using the holder for its use by ambulance personnel during transportation of the patient to the treatment center. The device has large dimensions and provides mechanical fixation of the ultrasonic sensor on the patient’s head, which also makes it impossible for prolonged use because of the patient’s discomfort, up to pain.

The task to which the present utility model is directed is to create a compact device for mounting an ultrasonic sensor when conducting research in different conditions: a hospital, an outpatient clinic, as well as autonomous research, including monitoring while maintaining the high quality of the results.

The problem is solved due to the fact that the device for attaching the ultrasonic sensor to the human body, including a sphere-shaped sleeve, mounted with the possibility of its angular positioning and made with the possibility of placing an ultrasonic sensor in it, according to the technical solution, includes a housing and a fixing cover, while the sphere-shaped sleeve is made in the form of a springy split sleeve, the outer surface of which has the shape of a sphere truncated by two parallel planes, and the sleeve is installed in the through channel of the housing with the exception of the possibility of its falling out from the side of the working surface of the housing, made possible to be attached to the human body, and the fixing cover is installed on the opposite side of the housing with the possibility of fixing the sphere-shaped sleeve in the selected angular position and has a through hole coaxial with through channel of the housing.

The working surface of the housing can be made with the possibility of placing on it an adhesive pad for attachment to the human body.

The through channel of the housing may be cylindrical and provided with restrictive protrusions.

The sphere-shaped sleeve may have a seat socket complementary to the shape of an ultrasonic sensor.

The locking cover can be mounted on the housing by means of a threaded connection.

The cuts on the spherical spring sleeve can be made alternately from opposite sides.

The technical result achieved by the above set of features is to simplify the design of the device, providing a simple and reliable angular positioning of the ultrasonic sensor with the fixation of the selected position.

The essence of the claimed device is illustrated by the drawing, which does not cover and, moreover, does not limit the scope of claims for this decision, but is only illustrative material of a particular case of the device.

Figure 1 shows a device for attaching an ultrasonic sensor to a human body, a longitudinal section.

A device for attaching an ultrasonic sensor to a human body includes a sphere-shaped sleeve 1, a housing 2 and a fixing cover 3. The sphere-shaped sleeve 1 is made in the form of a spring-loaded split sleeve, the outer surface of which has the shape of a sphere truncated by two parallel planes. Its internal structural implementation provides the possibility of placing an ultrasonic sensor in it. The housing 2 has a working surface 4, made with the possibility of attachment to the human body. A through channel 5 is made in the housing 2. A sphere-shaped sleeve 1 is installed in the through channel 5 of the housing 2 with the exception of the possibility of its falling out from the side of the working surface 4. On the side opposite to the working surface, the fixing cover 3 is installed on the housing 2. The fixing cover 3 has a through hole 6, coaxial with the through channel 5 of the housing 2.

On the previously identified zone of stable registration of the Doppler signal, the device is installed in such a way that the working surface 4 of the housing 2 is adjacent to the human body. For this, the housing 2 has a working surface 4, made with the possibility of attachment to the human body. In a preferred embodiment of the device, the working surface 4 of the housing 2 can be made with the possibility of placing on it an adhesive strip for attachment to the human body. In other embodiments, the working surface 4 of the housing 2 can be made in the form of a suction cup, or with the possibility of placing on it a viscous gel-like layer with high adhesive properties for attachment to the human body, or surface 4 can be made with the possibility of attaching to the human body by means of liquid body glue.

Through a through hole 6 of the fixing cover 3 and a sphere-shaped sleeve 1, a small amount of ultrasonic gel is applied to the human body. Next, an ultrasonic sensor is placed in a sphere-shaped sleeve 1, moving it along the axis of the sleeve until it contacts the gel to ensure ultrasonic contact with the patient’s skin. The possibility of placing the ultrasonic sensor is due to the alignment of the through hole 6 of the fixing cover and the through channel 5 of the housing 2, in which a sphere-shaped sleeve 1 is installed, the design of which makes it possible to place an ultrasonic sensor in it, for example, due to the mounting socket made in it, a complementary form of the ultrasonic sensor .

Next, the angle of the ultrasonic sensor is changed, achieving a stable registration of the Doppler signal when an ultrasound beam hits the diagnosed vessel. This is due to the fact that the outer surface of the sphere-shaped sleeve 1, in which the ultrasonic sensor is placed, is made in the form of a sphere truncated by two parallel planes, which allows the sphere-shaped sleeve 1 to change its angle of inclination relative to the through channel 5 of the housing 2, in which it is installed with with the exception of the possibility of its loss from the side of the working surface 4. In this case, the sphere-shaped sleeve 1 slides part of its outer surface along the wall of the through channel 5.

Examples of the through channel 5 of the housing 2 can be a cylindrical channel provided with restrictive protrusions, or the through channel 5 can be made conical, tapering towards the working surface 4 of the housing 2, or the through channel 5 can be made as a part of a sphere complementary to the shape of the sleeve.

After finding the optimal position of the ultrasonic sensor, it is fixed with a fixing cover 3. This is due to the fact that the sphere-shaped sleeve 1 is made in the form of a spring split sleeve. When fixing a sphere-shaped sleeve 1 with a locking cover 3, its deformation occurs. In this case, the elastically deformable parts of the sphere-shaped sleeve 1, formed by cuts, the so-called "petals", which have a springy effect, compress the ultrasonic sensor, fixing it relative to the sphere-shaped sleeve 1. At the same time, the sphere-shaped sleeve 1 is pressed against the wall of the through channel 5 in the selected position due to the fact that the sphere-shaped sleeve 1 is placed with the exception of the possibility of its falling out of the through channel 5 from the side of the working surface 4 of the housing 2, and the fixing cover 3 is installed on the housing 2 with hand, the opposite side of the working surface 4. In a preferred embodiment, the locking cover 3 is mounted on the housing 2 by a threaded connection that enables to adjust the degree of pressing of a sphere-like sleeve 1, but are possible embodiments of the connection using screws or attracting via the latching mechanism. In addition, for a more efficient fixation of the sphere-shaped sleeve 1 in a selected position, a sealing ring can be installed between the housing 2 and the fixing cover 3.

In a preferred embodiment of the device, the elastically deformable parts of the sphere-shaped sleeve 1 are formed by cuts made alternately from opposite sides, for example, four cuts through 90 °, the 1st and 3rd from one side of the spherical sleeve 1, and the 2nd and 4th from the opposite side. This embodiment of the cuts makes it possible to achieve a denser compression by the spherical sleeve 1 of the ultrasonic sensor and a more tight compression of the sphere-shaped sleeve 1 against the wall of the through channel 5 of the housing 2 in the selected position, which in turn improves the angular positioning of the ultrasonic sensor and fixes the selected position. In other embodiments of the device, cuts on a spherical spring can be made on one side of it.

A device for attaching an ultrasonic sensor to the human body can be installed on the head, mainly on the region of the acoustic window of the temporal bone, and can also be used to conduct ultrasound examinations or procedures on other parts of the human body while maintaining the functions of manual positioning of the sensor, the requirements for it installation, and providing a simple and reliable mechanism for its angular positioning and fixing in the selected position.

Claims (6)

1. A device for attaching an ultrasonic sensor to a human body, including a sphere-shaped sleeve, mounted with the possibility of its angular positioning and made with the possibility of placing an ultrasonic sensor in it, characterized in that the device includes a housing and a fixing cover, while the sphere-shaped sleeve is made in the form spring-loaded split sleeve, the outer surface of which has the shape of a sphere truncated by two parallel planes, and the sleeve is installed in the through channel of the housing with a suit so me possibility of its falling out from the working surface of the housing, adapted to enable fastening of the human body, and the fixing cap mounted on the opposite side of the housing to enable locking sphere-like sleeve in a selected angular position and has a through hole coaxial with a through body passage. 2. The device according to p. 1, characterized in that the working surface of the housing is made with the possibility of placing on it an adhesive pad for attachment to the human body. 3. The device according to p. 1, characterized in that the through channel of the housing is cylindrical and provided with restrictive protrusions. 4. The device according to p. 1, characterized in that the sphere-shaped sleeve has a seat socket complementary to the shape of an ultrasonic sensor. 5. The device according to p. 1, characterized in that the locking cover is mounted on the housing by means of a threaded connection. 6. The device according to claim 1, characterized in that the cuts on the spherical spring sleeve are made alternately from opposite sides.

Images