CN112022212A - Double-probe palm ultrasonic diagnostic apparatus - Google Patents

Abstract

The invention relates to the technical field of ultrasonic diagnostic instruments, and discloses a double-probe handheld ultrasonic diagnostic instrument which comprises an instrument body, wherein a host computer which is in wireless communication with an external display terminal is arranged in the instrument body, a convex array probe and a linear array probe are respectively arranged at two ends of the instrument body, and the convex array probe and the linear array probe are respectively and electrically connected with the host computer; the machine body is flat, the two sides of the machine body form holding sides for a user to hold, and the holding sides are bent inwards in an arc shape along the direction from the end part to the middle part of the machine body; the double-probe palm ultrasonic diagnostic apparatus provided by the invention has the advantages that the convex array probe and the linear array probe are arranged on the body, so that ultrasonic scanning of different parts to be scanned can be met; the main machine is arranged in the machine body, and data of ultrasonic scanning of the convex array probe and the linear array probe can be processed in the main machine and then transmitted to the display terminal for display through wireless communication, so that the use is convenient.

Description

Double-probe palm ultrasonic diagnostic apparatus

Technical Field

The invention relates to the technical field of ultrasonic scanning, in particular to a double-probe handheld ultrasonic diagnostic apparatus.

Background

Ultrasonic scanning is to scan a human body by using ultrasonic waves, and then internal images of the scanned human body are formed on a display screen, so that a doctor can conveniently watch the internal images of the human body.

At present, there are many portable ultrasonic diagnostic apparatuses in the market, which include an apparatus body, a probe is arranged on the apparatus body, and a user can scan and image the inside of a human body by holding the apparatus body by hand and pressing the probe against the human body.

In the prior art, the ultrasonic diagnostic apparatus is a single probe, so that the ultrasonic scanning can be carried out only by using the single probe, and thus, when a plurality of parts are required to be detected, if the probe does not meet the requirement of the scanning part, the ultrasonic diagnostic apparatus needs to be replaced, so that the requirement of the scanning of the plurality of parts is difficult to meet by the ultrasonic diagnostic apparatus.

Disclosure of Invention

The invention aims to provide a double-probe handheld ultrasonic diagnostic apparatus, and aims to solve the problem that the ultrasonic diagnostic apparatus only has a single probe in the prior art.

The invention is realized in this way, the double-probe palm ultrasonic diagnostic apparatus, including the organism, there is host computer in wireless communication with the display terminal of the outside in the said organism, both ends of the said organism set up protruding matrix probe and linear array probe separately, said protruding matrix probe and linear array probe are connected with electrical behavior of the host computer separately; the machine body is flat, two sides of the machine body form a hand holding side for a user to hold, and the hand holding side is bent towards an inner arc shape along the direction from the end part to the middle part of the machine body.

Furthermore, the convex array probe is provided with a convex array end face which is abutted against the scanning part, and the convex array end face is a curved face with the middle part protruding outwards along the extending direction between the two hand-held sides of the machine body.

Furthermore, a detachable convex matrix shell is sleeved at the end part of the machine body, and the convex matrix end face is formed on the convex matrix shell; a plurality of sunken longitudinal nicks and a plurality of sunken transverse nicks are arranged on the convex array end surface, and the longitudinal nicks and the transverse nicks respectively penetrate through the edge of the convex array end surface; the longitudinal nicks and the transverse nicks are respectively arranged on the convex array end face in a grid shape in a staggered communication mode.

Further, a lateral swing plate is arranged at the end part of the machine body, and the lateral swing plate swings up and down along the bending direction of the convex array end face by taking the middle part of the lateral swing plate as a swing center; the convex array shell is sleeved on the periphery of the lateral swing plate and is connected with the lateral swing plate in a clamping mode.

Further, a first step ring which faces the convex array shell and is arranged around the periphery of the machine body is arranged on the periphery of the end portion of the machine body, and a first elastic layer is laid on the first step ring; the bottom of the convex array shell is provided with a convex array abutting surface which is arranged towards the first step ring, and the convex array abutting surface is fixedly abutted on the first elastic layer.

Further, the thickness of the first elastic layer is gradually increased along the direction from the convex array abutting surface to the first step ring.

Further, the linear array probe is provided with a linear array end face abutted against the scanning part, the linear array end face is a flat surface along the extending direction between two hand-held sides of the machine body, an arc-shaped convex strip is convexly arranged in the middle of the linear array end face, and the arc-shaped convex strip extends along the extending direction between the two hand-held sides of the machine body.

Furthermore, a detachable linear array shell is sleeved at the end part of the machine body, and the linear array end face is formed on the linear array shell; be provided with a plurality of sunken direction nicks on the arc sand grip, the direction nick along the crooked extension of width direction of arc sand grip is arranged, and link up the edge of arc sand grip.

Further, two end side faces which are formed between the two hand-held sides and are arranged oppositely are arranged on the machine body; the end part of the machine body is provided with an end direction swinging plate, and the end direction swinging plate swings up and down between the side surfaces of the two end parts by taking the middle part of the end direction swinging plate as a swinging center; the convex array shell is sleeved on the periphery of the end direction swinging plate and is connected with the end direction swinging plate in a clamping mode.

Further, a second step ring which faces the linear array shell and is arranged around the periphery of the machine body is arranged on the periphery of the end portion of the machine body, and a second elastic layer is laid on the second step ring; the bottom of the linear array shell is provided with a linear array abutting surface which is arranged towards the second step ring, and the linear array abutting surface is fixedly abutted on the second elastic layer.

Compared with the prior art, the double-probe palm ultrasonic diagnostic apparatus provided by the invention has the advantages that the convex array probe and the linear array probe are arranged on the body, so that ultrasonic scanning of different parts to be scanned can be met; the main machine is arranged in the machine body, and data of ultrasonic scanning of the convex array probe and the linear array probe can be processed in the main machine and then transmitted to the display terminal for display through wireless communication, so that the use is convenient.

Drawings

FIG. 1 is a schematic front view of a dual-probe palm ultrasonic diagnostic device provided by the invention;

FIG. 2 is a schematic front view of a convex array end face provided by the present invention;

fig. 3 is a schematic front view of the end face of the linear array provided by the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The following describes the implementation of the present invention in detail with reference to specific embodiments.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that if there is an orientation or positional relationship indicated by the terms "upper", "lower", "left", "right", etc. based on the orientation or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but it is not intended to indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and are not to be construed as limiting the present patent, and the specific meaning of the terms may be understood by those skilled in the art according to specific circumstances.

Referring to fig. 1-3, preferred embodiments of the present invention are shown.

A double-probe handheld ultrasonic diagnostic apparatus comprises an apparatus body 101, wherein a host computer in wireless communication with an external display terminal is arranged in the apparatus body 101, and the host computer is used as a control center and can process data and the like. The two ends of the body 101 are respectively provided with a convex probe 201 and a linear probe 301, the convex probe 201 is used for carrying out ultrasonic scanning on the abdomen, the heart, the small organs and the like, and the linear probe 301 is used for carrying out ultrasonic scanning on the body surface, the blood vessels and the like. The convex array probe 201 and the linear array probe 301 are respectively electrically connected with a host, and data scanned by the convex array probe 201 and the linear array probe 301 are directly transmitted to the host for processing and then transmitted to the display terminal by the host for displaying.

The body 101 is flat, two sides of the body 101 form a hand-held side 102 for a user to hold, and the hand-held side 102 is curved inward in an arc shape along a direction from the end to the middle of the body 101.

In the double-probe handheld ultrasonic diagnostic apparatus, the convex probe 201 and the linear probe 301 are arranged on the body 101, so that ultrasonic scanning of different parts to be scanned can be met; the main machine is arranged in the machine body 101, and the ultrasonic scanning data of the convex probe 201 and the linear probe 301 can be processed in the main machine and then transmitted to the display terminal for display through wireless communication, so that the use is convenient.

The convex probe 201 has a convex end face 202 abutting against a scanning portion, and the convex end face 202 is a curved face having a middle portion protruding outward along an extending direction between the two hand-held sides 102 of the body 101.

A detachable convex matrix shell is sleeved at the end part of the machine body 101, and a convex matrix end face 202 is formed on the convex matrix shell; a plurality of concave longitudinal scores 203 and a plurality of concave transverse scores 204 are arranged on the convex array end face 202, and the longitudinal scores 203 and the transverse scores 204 respectively penetrate through the edge of the convex array end face 202; the plurality of longitudinal scores 203 and the plurality of transverse scores 204 are respectively arranged on the convex array end face 202 in a grid shape in a staggered communication manner.

When the probe is used for ultrasonic scanning, a couplant needs to be coated on a part to be scanned, and the problem that the couplant is squeezed open and becomes thin frequently occurs in the moving process of the probe, so that the couplant needs to be coated repeatedly, and the operation is complicated. By arranging the transverse nicks 204 and the longitudinal nicks 203 which are arranged in a grid shape on the convex array end face 202, the couplant can be embedded into the transverse nicks 204 and the longitudinal nicks 203 in the process that the convex array end face 202 is abutted against a human body to move, and because the transverse nicks 204 and the longitudinal nicks 203 penetrate through the edge of the convex array end face 202, the convex array end face 202 cannot completely extrude and thin the couplant, and the couplant is continuously embedded into the transverse nicks 204 and the longitudinal nicks 203, so that the ultrasonic scanning precision is improved.

A lateral swing plate is arranged at the end part of the machine body 101, and the lateral swing plate swings up and down along the bending direction of the convex array end surface 202 by taking the middle part of the lateral swing plate as a swing center; the convex array shell is sleeved on the periphery of the lateral swing plate and is connected with the lateral swing plate in a clamping mode.

Like this, after protruding battle array terminal surface 202 butt is on waiting to scan the position, at the in-process that the extrusion removed, because the side direction swing board can be along the crooked orientation luffing motion of protruding battle array terminal surface 202, and then protruding battle array terminal surface 202 can swing for protruding battle array terminal surface 202 can with wait to scan the butt contact of more areas of position, improve ultrasonic scanning precision greatly.

A first step ring which faces the convex array shell and is arranged around the periphery of the machine body 101 is arranged on the periphery of the end part of the machine body 101, and a first elastic layer is laid on the first step ring; the bottom of the convex array shell is provided with a convex array abutting surface which is arranged towards the first step ring, and the convex array abutting surface is fixedly abutted on the first elastic layer.

The first elastic layer can realize limiting and positioning on the swing of the convex array shell, and the convex array shell is driven to automatically reset under the condition of no abutting pressure.

Along the direction of convex array butt joint face to first step ring, the thickness of first elastic layer increases gradually, strengthens the effect that first elastic layer drive convex array shell resets.

The linear array probe 301 has a linear array end face 302 abutting against a scanning part, the linear array end face 302 is a flat surface along an extending direction between two hand-held sides 102 of the body 101, an arc-shaped convex strip 303 is convexly arranged in the middle of the linear array end face 302, and the arc-shaped convex strip 303 extends along the two hand-held sides 102 of the body 101.

A detachable linear array shell is sleeved at the end part of the machine body 101, and a linear array end face 302 is formed on the linear array shell; the arc-shaped convex strip 303 is provided with a plurality of concave guide scores 304, and the guide scores 304 are arranged along the width direction of the arc-shaped convex strip 303 in a bending and extending manner and penetrate through the edge of the arc-shaped convex strip 303.

Thus, after the linear array end face 302 is abutted on the part to be scanned, and in the process of pushing the linear array end face 302 to move, the couplant is prevented from being completely squeezed open and thinned, and the couplant can be embedded in the guide notch 304, so that the precision of ultrasonic scanning is ensured.

Two end side surfaces which are formed between the two hand-held sides 102 and are arranged oppositely on the machine body 101; the end part of the machine body 101 is provided with an end direction swinging plate, and the end direction swinging plate takes the middle part as a swinging center and swings up and down between the side surfaces of the two end parts; the convex array shell is sleeved on the periphery of the end swinging plate and is connected with the end swinging plate in a clamping manner.

Thus, after the linear array end face 302 is abutted to the part to be scanned, in the process of extrusion movement, as the end-to-end swinging plate can swing up and down along the side faces of the two end parts, the linear array end face 302 can swing, so that the linear array end face 302 can be in abutting contact with more areas of the part to be scanned, and the ultrasonic scanning precision is greatly improved.

A second step ring which faces the linear array shell and is arranged around the periphery of the machine body 101 is arranged on the periphery of the end part of the machine body 101, and a second elastic layer is laid on the second step ring; the bottom of the linear array shell is provided with a linear array abutting surface which is arranged towards the second step ring, and the linear array abutting surface is fixedly abutted on the second elastic layer.

The second elastic layer can limit and position the swinging of the linear array shell, and the linear array shell is driven to automatically reset under the condition of no abutting pressure.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The double-probe palm ultrasonic diagnostic apparatus is characterized by comprising an apparatus body, wherein a host computer in wireless communication with an external display terminal is arranged in the apparatus body, a convex array probe and a linear array probe are respectively arranged at two ends of the apparatus body, and the convex array probe and the linear array probe are respectively and electrically connected with the host computer; the machine body is flat, two sides of the machine body form a hand holding side for a user to hold, and the hand holding side is bent towards an inner arc shape along the direction from the end part to the middle part of the machine body.

2. The palm-type ultrasonic diagnostic apparatus with two probes as claimed in claim 1, wherein said convex array probe has a convex array end surface abutting against the scanning portion, and said convex array end surface is a curved surface with a middle portion protruding outwards along the extending direction between the two hand-held sides of said body.

3. The dual-probe handheld ultrasonic diagnostic apparatus according to claim 2, wherein a detachable convex array shell is sleeved on the end portion of the body, and the convex array end face is formed on the convex array shell; a plurality of sunken longitudinal nicks and a plurality of sunken transverse nicks are arranged on the convex array end surface, and the longitudinal nicks and the transverse nicks respectively penetrate through the edge of the convex array end surface; the longitudinal nicks and the transverse nicks are respectively arranged on the convex array end face in a grid shape in a staggered communication mode.

4. The dual-probe handheld ultrasonic diagnostic apparatus according to claim 3, wherein a lateral swing plate is provided at an end of the body, and the lateral swing plate swings up and down along a bending direction of the convex array end face with a middle portion thereof as a swing center; the convex array shell is sleeved on the periphery of the lateral swing plate and is connected with the lateral swing plate in a clamping mode.

5. The dual-probe handheld ultrasonic diagnostic apparatus as defined in claim 4, wherein the outer periphery of the end of the body is provided with a first step ring facing the convex array shell and arranged around the outer periphery of the body, and a first elastic layer is laid on the first step ring; the bottom of the convex array shell is provided with a convex array abutting surface which is arranged towards the first step ring, and the convex array abutting surface is fixedly abutted on the first elastic layer.

6. The dual-probe palm ultrasonic diagnostic apparatus according to claim 5, wherein the thickness of the first elastic layer is gradually increased along the direction from the convex array abutting surface to the first step ring.

7. The dual-probe handheld ultrasonic diagnostic apparatus as claimed in any one of claims 2 to 6, wherein the linear array probe has a linear array end surface abutting against the scanning portion, the linear array end surface is a flat surface along the extending direction between the two hand-held sides of the body, the middle part of the linear array end surface is convexly provided with an arc-shaped convex strip, and the arc-shaped convex strip is arranged along the extending direction between the two hand-held sides of the body.

8. The dual-probe handheld ultrasonic diagnostic apparatus as defined in claim 7, wherein a detachable linear array shell is sleeved on the end of the body, and the linear array end face is formed on the linear array shell; be provided with a plurality of sunken direction nicks on the arc sand grip, the direction nick along the crooked extension of width direction of arc sand grip is arranged, and link up the edge of arc sand grip.

9. The dual-probe palm ultrasonic diagnostic device according to claim 8, wherein two end side faces of said body are formed between and oppositely disposed from the two hand-held sides; the end part of the machine body is provided with an end direction swinging plate, and the end direction swinging plate swings up and down between the side surfaces of the two end parts by taking the middle part of the end direction swinging plate as a swinging center; the convex array shell is sleeved on the periphery of the end direction swinging plate and is connected with the end direction swinging plate in a clamping mode.

10. The dual-probe handheld ultrasonic diagnostic apparatus as recited in claim 9, wherein the outer periphery of the end of the body is provided with a second step ring which faces the linear array housing and is arranged around the outer periphery of the body, and a second elastic layer is laid on the second step ring; the bottom of the linear array shell is provided with a linear array abutting surface which is arranged towards the second step ring, and the linear array abutting surface is fixedly abutted on the second elastic layer.

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