CN218720850U - Atmosphere lamp subassembly and ultrasonic diagnostic instrument - Google Patents

Abstract

The utility model discloses an atmosphere banks spare and adopt ultrasonic diagnostic instrument of this atmosphere banks spare, this atmosphere banks spare include first connecting pipe, first light emitting component and first optic fibre. One end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other; the first light-emitting element is connected to the first connecting groove; the first optical fiber is provided with a first end and a second end which are opposite, the first end is connected with the second connecting groove, and light rays emitted by the first light-emitting element can enter the first end and are conducted to the second end; wherein the first optical fiber is at least partially used for being arranged on the periphery of a control panel of the ultrasonic diagnostic apparatus or the periphery of a probe cover of the ultrasonic diagnostic apparatus. The utility model discloses an ultrasonic diagnosis appearance can reduce the light of penetrating user's eyes directly, travelling comfort when promoting ultrasonic diagnosis appearance and using.

Description

Atmosphere lamp subassembly and ultrasonic diagnostic instrument

Technical Field

The utility model relates to the technical field of medical equipment, in particular to atmosphere banks spare and ultrasonic diagnostic appearance.

Background

The ultrasonic diagnostic apparatus is generally provided with an atmosphere lamp, the atmosphere lamp can identify the position of the ultrasonic diagnostic apparatus when the ultrasonic diagnostic apparatus is used in dim light on one hand, and different use scenes of the ultrasonic diagnostic apparatus can be identified by changing the color of the atmosphere lamp on the other hand. An atmosphere lamp on an existing ultrasonic diagnostic apparatus adopts a plurality of lamp beads in linear arrangement to emit light, and the lamp beads are combined to form a strip-shaped lamp belt. And among the above-mentioned luminous mode, every lamp pearl all is along direction emission light all around to when making the user observe atmosphere lamp, easily make too much light penetrate user's eyes directly, cause user's discomfort.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an atmosphere banks spare and ultrasonic diagnosis appearance can reduce the light of penetrating user's eyes directly, travelling comfort when promoting the ultrasonic diagnosis appearance and using.

In order to achieve the above object, the present invention provides an atmosphere lamp assembly for an ultrasonic diagnostic apparatus, which includes a first connection tube, a first light emitting element and a first optical fiber. One end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other; the first light-emitting element is connected to the first connecting groove; the first optical fiber is provided with a first end and a second end which are opposite, the first end is connected with the second connecting groove, and light rays emitted by the first light-emitting element can enter the first end and are conducted to the second end; wherein the first optical fiber is at least partially used for being arranged on the periphery of a control panel of the ultrasonic diagnostic apparatus or the periphery of a probe cover of the ultrasonic diagnostic apparatus.

The utility model also provides an ultrasonic diagnostic apparatus, including display, control panel and host computer. Display and control panel electricity respectively connect in the host computer, and the host computer includes mainframe shell, socket and atmosphere banks spare, and the mainframe shell includes the shell main part and covers with the detachable probe of being connected of shell main part, and the socket is connected in the shell main part, and the socket is used for the electricity to connect the probe, and the probe covers and covers the socket, and the atmosphere banks spare includes: one end of the first connecting pipe is concavely provided with a first connecting groove, the other opposite end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other; a first light emitting element connected to the first connection groove; the first optical fiber is provided with a first end and a second end which are opposite, the first end is connected with the second connecting groove, and light emitted by the first light-emitting element can enter the first end and is conducted to the second end; wherein the first optical fiber is at least partially arranged at an outer periphery of the control panel or an outer periphery of the probe cover.

According to some embodiments of the invention, the end surface of the first end is arranged spaced apart from the first light emitting element.

According to some embodiments of the utility model, be equipped with the annular arch that is located between first spread groove and the second spread groove in the first spread groove, the bellied inside through-hole of annular communicates first spread groove and second spread groove respectively, and the annular arch has the ring terminal surface that deviates from first light emitting component, the terminal surface towards first light emitting component of the first end of ring terminal surface butt.

According to some embodiments of the utility model, the axis of first connecting groove coincides with the axis of second connecting groove.

According to some embodiments of the present invention, a direction along the first connecting groove toward the second connecting groove is a first direction, along which a cross-sectional area of the first connecting groove perpendicular to the first direction is gradually reduced, the first light emitting element being in interference fit with the first connecting groove; and/or the direction pointing to the second connecting groove along the first connecting groove is a first direction, the cross-sectional area of the second connecting groove perpendicular to the first direction is gradually reduced along the reverse direction of the first direction, and the first end is in interference fit with the second connecting groove.

According to some embodiments of the utility model, first connecting groove includes first groove section and the second groove section that communicates with first groove section, the second groove section is located the tip that first connecting pipe deviates from the second connecting groove, the internal diameter of second groove section is greater than the internal diameter of first groove section, the inner periphery of second groove section includes first arcwall face and the first plane of being connected with first arcwall face, light emitting component includes the illuminating part and connects in the connecting portion of the one end of illuminating part, first groove section is located to the illuminating part, second groove section is located to connecting portion, the periphery of connecting portion has second arcwall face and the second plane of being connected with the second arcwall face, the first arcwall face of second arcwall face butt, the first plane of second plane butt.

According to some embodiments of the invention, the first optical fiber is arranged around a periphery of the control panel, the second end extends to a side of the light emitting element facing away from the first end, and the second end is arranged opposite to the first light emitting element at an interval; or the first optical fiber is arranged around the periphery of the probe cover, the second end extends to one side of the light-emitting element, which is far away from the first end, and the second end and the first light-emitting element are oppositely arranged at intervals.

According to some embodiments of the present invention, one end of the second connecting pipe is concavely provided with a third connecting groove, the other end of the second connecting pipe is concavely provided with a fourth connecting groove, and the third connecting groove and the fourth connecting groove are communicated with each other; the second light-emitting element is connected to the third connecting groove; and the second end is connected to the fourth connecting groove, and light emitted by the second light-emitting element can enter the second end and is conducted to the first end.

According to some embodiments of the present invention, one end of the third connecting pipe is concavely provided with a fifth connecting groove, the other end of the third connecting pipe is concavely provided with a sixth connecting groove, and the fifth connecting groove and the sixth connecting groove are communicated with each other; the third light-emitting element is arranged in the fifth connecting groove; the second optical fiber is provided with a third end and a fourth end which are oppositely arranged, the third end is connected with the sixth connecting groove, and light emitted by the third light-emitting element can enter the third end and is conducted to the fourth end; wherein the second optical fiber is at least partially arranged at the outer periphery of the control panel or the outer periphery of the probe cover.

According to some embodiments of the present invention, the second optical fiber and the first optical fiber are disposed around the periphery of the control panel, and the first light emitting element and the third light emitting element are disposed opposite to each other, and the second end and the fourth end are disposed opposite to each other; or the second optical fiber and the first optical fiber are arranged around the periphery of the probe cover together, the first light-emitting element and the third light-emitting element are arranged oppositely, and the second end and the fourth end are arranged oppositely.

According to some embodiments of the present invention, the control panel comprises a first plate body, a first accommodating groove extending along a circumferential direction of the first plate body is provided at an outer periphery of one side wall of the first plate body, and the atmosphere lamp assembly is provided in the first accommodating groove; the control panel also comprises a first light-transmitting cover plate, and the first light-transmitting cover plate is arranged at the notch position of the first accommodating groove in a covering manner; or a second accommodating groove extending along the circumferential direction covered by the probe is arranged on the periphery of one side wall covered by the probe, and the atmosphere lamp assembly is arranged in the second accommodating groove; the probe covers still includes second printing opacity apron, and the notch position of second holding tank is located to second printing opacity apron lid.

According to some embodiments of the present invention, the control panel includes a first plate body, a first accommodating groove extending along a circumferential direction of the first plate body is provided at an outer periphery of one side wall of the first plate body, the atmosphere lamp assembly is provided in the first accommodating groove, the control panel further includes a first light-transmitting cover plate, and the first light-transmitting cover plate is covered at a notch position of the first accommodating groove; the wall surface of the first light-transmitting cover plate facing the first accommodating groove is provided with a third accommodating groove, the third accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the first optical fiber, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate is abutted against the wall surface of the first connecting pipe, a second rib plate is arranged in the first accommodating groove, and the second rib plate is abutted against the wall surface of the first connecting pipe; or the periphery of one side wall of the probe cover is provided with a second accommodating groove extending along the circumferential direction of the probe cover, the atmosphere lamp assembly is arranged in the second accommodating groove, the probe cover further comprises a second light-transmitting cover plate, and the second light-transmitting cover plate is arranged at the notch position of the second accommodating groove in a covering manner; the second printing opacity apron is equipped with the fourth holding tank towards the wall of second holding tank, and the second that holds first optic fibre is constituteed jointly to fourth holding tank and second holding tank holds the chamber, and second printing opacity apron is equipped with the third gusset, and the wall of first connecting pipe of third gusset butt is equipped with the fourth gusset in the second holding tank, the wall of first connecting pipe of fourth gusset butt.

According to some embodiments of the present invention, the control panel includes a first plate body, a first accommodating groove extending along a periphery of a side wall of the first plate body is provided at a periphery of the first plate body, the atmosphere lamp assembly is disposed in the first accommodating groove, the control panel further includes a first light-transmitting cover plate, the first light-transmitting cover plate is covered at a notch position of the first accommodating groove, a third accommodating groove is provided at a wall surface of the first light-transmitting cover plate facing the first accommodating groove, the third accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the atmosphere lamp assembly, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate abuts against a wall surface of the first connecting pipe facing a side of the first light-transmitting cover plate, a second rib plate is provided in the first accommodating groove, the second rib plate abuts against a wall surface of the first connecting pipe facing away from the periphery of the first plate body; a third plane is arranged on one side, away from the first plate body, of the first connecting pipe, and the first rib plate abuts against the third plane; or, the periphery of one side wall of the probe cover is provided with a second accommodating groove extending along the periphery of the probe cover, the atmosphere lamp assembly is arranged in the second accommodating groove, the probe cover further comprises a second light-transmitting cover plate, the second light-transmitting cover plate is arranged at the notch position of the second accommodating groove in a covering manner, the wall surface of the second light-transmitting cover plate facing the second accommodating groove is provided with a fourth accommodating groove, the fourth accommodating groove and the second accommodating groove jointly form a second accommodating cavity for accommodating the atmosphere lamp assembly, the second light-transmitting cover plate is provided with a third rib plate, the third rib plate is abutted against the wall surface of the first connecting pipe facing one side of the second light-transmitting cover plate, a fourth rib plate is arranged in the second accommodating groove, and the fourth rib plate is abutted against the wall surface of the first connecting pipe facing away from one side of the periphery of the probe cover; one side of the first connecting pipe facing the second light-transmitting cover plate is provided with a fourth plane, and the first rib plate is abutted against the fourth plane.

The utility model also provides an ultrasonic diagnostic apparatus, including display, control panel and host computer. Control panel and display electricity respectively connect in the host computer, and the host computer includes mainframe shell, socket and atmosphere banks spare, and the socket is connected in the mainframe shell, and the socket is used for the electricity to connect the probe, its characterized in that, the atmosphere banks spare includes: one end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other; the first light-emitting element is arranged in the first connecting groove; the first optical fiber is provided with a first end and a second end which are opposite, the first end is connected with the second connecting groove, and light rays emitted by the first light-emitting element can enter the first end and are conducted to the second end; the ultrasonic diagnostic apparatus comprises a first plate body and a second plate body, wherein the first plate body is connected with the second plate body, an exposed seam is formed between the first plate body and the second plate body, and at least part of the first optical fiber is arranged at the seam.

Compared with the prior art, the beneficial effects of the utility model are that:

the technical scheme of the utility model in, the light that first light emitting component sent propagates to the second end of first optic fibre along the length direction of first optic fibre behind the first end that gets into first optic fibre, adopts first optic fibre to show to be rectangular form light band effect in this scheme promptly. Compare in adopting a plurality of lamp pearls that are linear arrangement to show the technical scheme of light band effect among the prior art, the light of first light emitting component transmission can not penetrate user's eyes directly to travelling comfort when having promoted the user and having observed the atmosphere lamp. And moreover, the first optical fiber is adopted to conduct light, so that the light-emitting effect is softer and more uniform.

And the first optical fiber of the atmosphere lamp is arranged at the periphery of the probe cover or the periphery of the control panel, when the ultrasonic diagnostic apparatus is in a dim light environment, the atmosphere lamp can mark the arrangement position of the probe cover or the control panel and also can show at least partial outline of the probe cover or the control panel, so that a user can accurately observe the arrangement position of the probe cover or the control panel.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an ultrasonic diagnostic apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a main body of the ultrasonic diagnostic apparatus shown in FIG. 1;

FIG. 3 is a schematic diagram of the arrangement of the probe cover and the first optical fiber of the ultrasonic diagnostic apparatus shown in FIG. 2;

FIG. 4 is a schematic view of the ultrasonic diagnostic apparatus of FIG. 3 in which a first optical fiber is mounted on a probe cover;

fig. 5 is a schematic structural view of a second light-transmitting cover plate of the ultrasonic diagnostic apparatus shown in fig. 3;

FIG. 6 is a schematic view of an atmosphere lamp assembly viewed in a first direction;

FIG. 7 is a schematic view of the atmosphere lamp assembly of FIG. 6 viewed from another direction;

FIG. 8 is a cross-sectional view of the atmosphere lamp assembly shown in FIG. 7;

FIG. 9 is a cross-sectional view of an exploded view of the atmosphere lamp assembly shown in FIG. 8;

FIG. 10 is an enlarged view taken at A of FIG. 9;

FIG. 11 is a schematic diagram of the first and second light transmissive cover plates assembled with the ambient lamp assembly;

FIG. 12 is a cross-sectional view of the schematic structure shown in FIG. 11 taken in a cross-section perpendicular to the axis of the first optical fiber;

FIG. 13 is a schematic structural diagram of the control panel shown in FIG. 1;

FIG. 14 is an exploded view of the control panel of FIG. 13;

fig. 15 is a schematic view of an inner side structure of the control panel shown in fig. 14.

The reference numbers indicate:

10-ultrasonic diagnostic equipment;

100-a host; 110-a main chassis; 111-a shell body; 112-probe covering; 113-a second light transmissive cover plate; 1131 — a fourth accommodating groove; 1132-third web; 130-a probe;

200-a control panel; 210-a first plate body; 211-a first receiving groove; 212-second web; 220-a first light transmissive cover plate; 221-a third holding tank; 222-first web;

300-atmosphere lamp assembly; 310-a first connection tube; 311-first connecting slot; 312-a first groove section; 313-a second groove section; 3131-a first arc-shaped face; 3132 — a first plane; 314-a second connection slot; 315-annular projection; 3151-annular end face; 316-third plane; 317-a fourth plane; 320-a first light emitting element; 321-a connecting part; 3211-a second plane; 3212-second arc surface; 322-a light emitting section; 330-a first optical fiber; 331-a first end; 332-a second end; 340-a second connecting tube; 341-third connecting groove; 342-a fourth connecting groove; 350-a second light emitting element; 360-a second optical fiber;

400-a mounting seat;

500-a first robot arm;

600-a second robotic arm;

700-a display;

800-socket.

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back \8230;) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the motion situation, and the like in a specific posture, and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if the meaning of "and/or", "and/or" and/or "appears throughout this document, it includes three parallel schemes, such as" a and/or B ", including a scheme, or B scheme, or a scheme satisfied by both a and B. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention provides an ultrasonic diagnostic apparatus 10, where the ultrasonic diagnostic apparatus 10 includes a display 700, a control panel 200, and a host 100. In some embodiments, the ultrasonic diagnostic apparatus 10 may further include a mount 400, a first robotic arm 500, and a second robotic arm 600. The mount 400 is connected to the upper side of the main body 100, and one end of the first robot 500 is connected to the mount 400 and the other end is connected to the control panel 200. The second robot 600 has one end connected to the first robot 500 at the end away from the mounting base 400 and the other end connected to the display 700. The display 700 may display pattern information as well as text information. At least one of a physical button, a physical knob, or a touch screen may be disposed on the control panel 200, and the control parameters of the ultrasonic diagnostic apparatus 10 may be adjusted by operating the physical button, the physical knob, or the touch screen.

The main body 100 includes a main chassis 110, a socket 800, and an atmosphere lamp assembly 300. The main chassis 110 includes a chassis main body 111 and a probe cover 112. The socket 800 and the atmosphere lamp assembly 300 are both mounted to the housing main body 111. In some embodiments, the ultrasonic diagnostic apparatus 10 may further include the probe 130, and the probe 130 is electrically connected to the socket 800, so as to achieve the purpose of electrically connecting the probe 130 with the control motherboard in the host 100. After the probe 130 is electrically connected to the control motherboard, on one hand, the probe can obtain electrical energy from the host 100, on the other hand, the probe can transmit the detected data to the control motherboard, the control motherboard performs analysis processing on the data to form an image signal, and the display 700 displays a corresponding image after obtaining the image signal.

The control panel 200 and/or the mainframe 100 of the ultrasonic diagnostic apparatus 10 are provided with an atmosphere lamp assembly 300, and the atmosphere lamp assembly 300 includes a first connection tube 310, a first light emitting element 320, and a first optical fiber 330. Referring to fig. 6 to 11, the first connection pipe 310 has opposite ends, one end of which is recessed with a first connection groove 311, the opposite end of which is recessed with a second connection groove 314, and the first connection groove 311 and the second connection groove 314 are communicated with each other. In other words, the first connection groove 311 is recessed for installing the first light emitting element 320, and the second connection groove 314 is recessed for installing the first optical fiber 330. The first connection groove 311 and the second connection groove 314 are connected to each other, so that light generated by the first light emitting element 320 is transmitted to the first end 331 of the first optical fiber 330, and thus the light emitted by the first light emitting element 320 is more fully utilized by the first optical fiber 330.

It is understood that the first end 331 of the first optical fiber 330 may be spaced apart from the first light emitting element 320, and the first end 331 of the first optical fiber 330 and the first light emitting element 320 may abut each other. To avoid the position of the first light emitting element 320 from interfering with the first optical fiber 330, referring to fig. 6-11 and 14, in some embodiments the first light emitting element 320 is spaced apart from the first optical fiber 330. The first optical fiber 330 and the first light emitting element 320 are spaced apart from each other, so that the first light emitting element 320 can be prevented from protruding out of the first optical fiber 330 during the process of assembling the first optical fiber 330 and the first light emitting element 320 on the first connecting tube 310. The arrangement of the spacing can reduce the accuracy of the first light emitting element 320 and the first optical fiber 330 in the assembling process, and improve the convenience of the assembly. Since the light emitted from the first light emitting element 320 is diffused, the first optical fiber 330 and the first light emitting element 320 are disposed in contact with each other, and the light emitted from the first light emitting element 320 is utilized by the first optical fiber 330 when the light is diffused to a small extent, so that the light emitted from the first light emitting element 320 can be utilized by the first optical fiber 330 more sufficiently by the contact arrangement of the first light emitting element 320 and the first optical fiber 330, and the overall light emitting intensity of the first optical fiber 330 is improved. Also, the abutting arrangement of the first light emitting element 320 and the first optical fiber 330 enables the fitting of the first light emitting element 320 and the first optical fiber 330 in the first connecting tube 310 to be more compact, and the stability of the assembly therebetween to be higher.

The first optical fiber 330 is elongated, and for convenience of description, two opposite ends of the first optical fiber 330 are defined as a first end 331 and a second end 332. Referring to fig. 6 to 11, the first end 331 of the first optical fiber 330 is connected to the second connection groove 314, and since the second connection groove 314 and the first connection groove 311 are communicated with each other and the first light emitting element 320 is connected to the first connection groove 311, light of the first light emitting element 320 can enter the first end 331 and be conducted to the second end 332. Wherein the first optical fiber 330 is at least partially disposed at the periphery of the control panel 200 of the ultrasonic diagnostic apparatus 10 or the periphery of the probe cover 112 of the ultrasonic diagnostic apparatus 10.

Here, the outer periphery of the control panel 200 of the ultrasonic diagnostic apparatus 10 or the outer periphery of the probe cover 112 of the ultrasonic diagnostic apparatus 10 will be specifically described. The outer periphery herein refers to a wall surface or an end surface of the control panel 200 of the ultrasonic diagnostic apparatus 10 or the probe cover 112 of the ultrasonic diagnostic apparatus 10 that can be seen by a user, for example, the first optical fiber 330 is arranged at least on the side surface of the control panel 200, the first optical fiber 330 is arranged at least on the upper surface of the control panel 200, the first optical fiber 330 is arranged at least on the edge of the side surface of the control panel 200 connected to the upper surface, the first optical fiber 330 is arranged at least on the side surface of the probe cover 112, the first optical fiber 330 is arranged at least on the front surface of the probe cover 112, and the first optical fiber 330 is arranged at least on the edge of the side surface of the probe cover 112 connected to the front surface. Here, it should be noted that the side surface of the control panel 200, the upper surface of the control panel 200, the side surface of the probe cover 112, and the front surface of the probe cover 112 are all exemplary illustrations, and are intended to mean that the first optical fiber 330 is arranged at least on the surface or edge of the control panel 200 or the probe cover 112 that can be directly observed by the user.

It should be understood that the term face or edge as used herein includes both flat faces or edges and also concave and convex faces or edges. Disposed on a flat face or edge, where the first optical fiber 330 is tiled; disposed on a concave-convex face or edge, the first optical fiber 330 may follow the contour of the face or edge, extend around the contour of the face or edge, and/or the first optical fiber 330 may bypass the recess, or the first optical fiber 330 may span the recess. The first optical fibers 330 may follow a straight path and the first optical fibers 330 may be arranged or extended in a curved, bent, coiled, stacked, etc. manner.

Referring to fig. 1 to 15, according to the technical solution of the present invention, light emitted from the first light emitting element 320 enters the first end 331 of the first optical fiber 330 and then propagates to the second end 332 of the first optical fiber 330 along the length direction of the first optical fiber 330, that is, the first optical fiber 330 is adopted in the present solution to display the long-strip-shaped optical tape effect. Compared with the technical scheme that the light band effect is displayed by a plurality of linearly arranged lamp beads in the prior art, the light emitted by the first light-emitting element 320 cannot directly irradiate the eyes of the user, so that the comfort of the user in observing the atmosphere lamp is improved. Moreover, the first optical fiber 330 is used for transmitting light, so that the light emitting effect is softer and more uniform.

Also, by disposing the first optical fiber 330 of the atmosphere lamp at the periphery of the probe cover 112 or at the periphery of the control panel 200, the atmosphere lamp assembly 300 can mark the arrangement position of the probe cover 112 or the control panel 200 when the ultrasonic diagnostic apparatus 10 is in a dark light environment, and can also show at least a partial outline of the probe cover 112 or the control panel 200, so that the user can accurately observe the arrangement position of the probe cover 112 or the control panel 200.

Referring to fig. 1 to 3, the present invention provides an ultrasonic diagnostic apparatus 10, wherein the ultrasonic diagnostic apparatus 10 includes a display 700, a control panel 200 and a host 100. The display 700 and the control panel 200 are electrically connected to the main unit 100, respectively, the display 700 is used to display a picture required by a user, so that the user can visually obtain required information, and the control panel 200 is used to implement the operation of the ultrasonic diagnostic apparatus 10 by the user.

The host 100 includes a host housing 110, a socket 800, and an atmosphere lamp. The main case 110 includes a case main body 111 and a probe cover 112, a cavity formed by the probe cover 112 and the case main body 111 is used for placing functional components of the ultrasonic diagnostic apparatus 10, and the environment where the functional components are located can be relatively sealed by the probe cover 112, so that the external impact on the components or dust accumulation is reduced, the protectiveness of the components inside the main case 100 is improved, and the service life of the ultrasonic diagnostic apparatus 10 is prolonged. The shell main body 111 is detachably connected with the probe cover 112, and the shell main body 111 is detachably connected with the probe cover 112, so that the installation and the overhaul of internal components of the shell main body 111 or the probe cover 112 are facilitated. It can be understood that the detachable connection mode of the shell main body 111 and the probe cover 112 may be a snap connection, a threaded connection, a pin connection, or the like, such that the shell main body 111 and the probe cover 112 are completely separated, or a hinge connection, or the like, in which a part of the shell main body 111 and the probe 130 are movably connected together, and another part of the shell main body 111 and the probe 130 can be opened and closed.

The socket 800 is connected to the case main body 111, and the socket 800 is covered by the probe cover 112 and electrically connected to the control main board inside the main case 110. The socket 800 is used for electrically connecting with the probe 130, so as to achieve the purpose of electrically connecting the probe 130 with the host 100. After the probe 130 is electrically connected to the host 100, on one hand, power can be obtained from the host 100, and on the other hand, detected data can be transmitted to the host 100, the host 100 obtains the data and then performs analysis processing to form an image signal, and the display 700 obtains the image signal and then displays a corresponding image.

It should be noted that the host 100 may include one socket 800, or may include a plurality of sockets 800. The ultrasonic diagnostic apparatus 10 may include one probe 130 or may include a plurality of probes 130. Illustratively, the ultrasonic diagnostic apparatus 10 may have 3 sockets 800 and 3 probes 130 corresponding thereto. For convenience of description, the following description will be given taking a configuration in which the main unit 100 includes one socket 800 and the ultrasonic diagnostic apparatus 10 has one probe 130.

The arrangement relationship between the end surface of the first end 331 and the first light emitting element 320 depends on the requirement. The first light emitting element 320 is used as a light source, and the first optical fiber 330 transmits light emitted by the first light emitting element 320 from the first end 331 to the second end 332, so that the purpose of emitting light by the first optical fiber 330 is finally achieved. Therefore, the positional relationship between the first optical fiber 330 and the first light emitting element 320 only needs to satisfy that the first optical fiber 330 can receive enough light emitted by the first light emitting element 320 to transmit the light from the first end 331 to the second end 332, so that the first optical fiber 330 emits light as a whole. Specifically, referring to fig. 5 to 8, the end surface of the first end 331 is spaced apart from the first light emitting element 320, and the end surface of the first end 331 is spaced apart from the light emitting element, so that a phenomenon that the light emitting element pushes the first end 331 out of the second connecting groove 314 during the installation process can be avoided, and the convenience of assembly is improved. Meanwhile, the end face of the first end 331 is spaced apart from the light emitting element, which can make the light generated by the optical fiber, especially the light generated by the first end 331, softer.

It is of course understood that in other embodiments, in particular, the first end 331 and the first light emitting element 320 may also be arranged in abutment. The first end 331 and the first light emitting element 320 are arranged in an abutting manner, so that the utilization rate of light emitted by the first light emitting element 320 is improved, and the conduction from the first end 331 to the second end 332 at a longer distance can be realized. Also, the first end 331 and the first light emitting element 320 are disposed in abutment, which can improve compactness of assembly, thereby improving stability of assembly.

It should be noted that the first light emitting element 320 and the first end 331 are separated from each other according to the actual situation, for example, for the first light emitting element 320 with the same power, when the first end 331 is separated from the first light emitting element 320 to a larger distance, the second end 332 of the first end 331, which can conduct light, is closer to the first end 331, and when the first end 331 is separated from the first light emitting element 320 to a smaller distance, the second end 332 of the first end 331, which can conduct light, is farther from the first end 331. The distance between the first light emitting element 320 and the first end 331 is adjusted according to the required distance from the first end 331 to the second end 332.

The first optical fiber 330 may have only the first end 331 provided with a light emitting element, or the first optical fiber 330 may have both the first end 331 and the second end 332 provided with a light emitting element. Considering that when only the first end 331 of the first optical fiber 330 is provided with a light emitting element, there is some attenuation in the light entering the first end 331 of the first optical fiber 330 after being transmitted to the second end 332 of the first optical fiber 330, which may reduce the uniformity of the light throughout the first optical fiber 330. In some embodiments, the first end 331 and the second end 332 of the first optical fiber 330 are provided with light emitting elements. Specifically, the atmosphere lamp assembly 330 further comprises a second connection tube 340 and a second light emitting element 350. One end of the second connection pipe 340 is concavely provided with a third connection groove 341, and the other end thereof is concavely provided with a fourth connection groove 342, and the third connection groove 341 and the fourth connection groove 342 are communicated with each other. The second light emitting element 350 is connected to the third connection groove 341. The second end 332 is connected to the fourth connecting groove 342, and light emitted from the second light emitting element 350 can enter the second end 332 and be conducted to the first end 331. The specific structure of the second connection pipe 340 can be referred to the first connection pipe 310, which is not described herein. In this scheme, both ends of first optic fibre 330 all can acquire light to make first optic fibre 330's luminous effect better, luminous effect everywhere in first optic fibre 330 is more even.

In order to efficiently adjust the distance from the first light emitting element 320 to the first end 331, referring to fig. 8, 9 and 10, specifically, the first connection pipe 310 is concavely provided with an annular protrusion 315 located between the first connection groove 311 and the second connection groove 314, an inner through hole of the annular protrusion 315 is respectively communicated with the first connection groove 311 and the second connection groove 314, the annular protrusion 315 has an annular end face 3151 departing from the first light emitting element 320, and the annular end face 3151 abuts against an end face of the first end 331 facing the first light emitting element 320. The annular protrusion 315 is disposed, and the first optical fiber 330 inserted into a certain position of the first connection tube 310 is abutted by the annular end face 3151, that is, is limited by the annular end face 3151. At this time, the distance from the first light emitting element 320 to the first optical fiber 330 can be adjusted only by adjusting the distance from the first light emitting element 320 to the annular end face 3151, so that the operation is convenient and the precision is guaranteed. Meanwhile, the design of the annular end face 3151 can avoid the phenomenon that the first optical fiber 330 protrudes too far towards the first light emitting element 320 to push out the first light emitting element 320 or the first optical fiber 330 itself is pushed out.

It is understood that, in other embodiments, specifically, the annular end face 3151 may be disposed to enable the first light emitting element 320 to be inserted into a certain position and then abutted, so as to adjust the distance between the first light emitting element 320 and the first optical fiber 330. Alternatively, the first annular end face 3151 may be provided to abut against both the first light emitting element 320 at a certain position and the first end 331 of the first optical fiber 330 at a certain position, thereby controlling the distance from the first light emitting element 320 to the first end 331.

Referring to fig. 6 to 9, the central axis of the first connection groove 311 coincides with the central axis of the second connection groove 314. Because the first connecting groove 311 is used for arranging the first light-emitting element 320, the second connecting groove 314 is used for arranging the first optical fiber 330, the cross section of the first light-emitting element 320 perpendicular to the axial direction is a circle, the cross section of the first optical fiber 330 perpendicular to the axial direction is a circle, and the central axis of the first connecting groove 311 coincides with the central axis of the second connecting groove 314, the axial coincidence of the first light-emitting element 320 and the first optical fiber 330 is realized after the first light-emitting element 320 and the first optical fiber 330 are arranged. This arrangement allows the light emitted from the first light emitting element 320 to be utilized more fully and uniformly by the first optical fiber 330.

It is understood that the arrangement of the central axes of the first connecting groove 311 and the second connecting groove 314 only needs to satisfy the requirement that the first optical fiber 330 arranged in the second connecting groove 314 can obtain enough intensity of light emitted by the first light-emitting element 320 arranged in the first connecting groove 311, and on the premise that the other embodiments are provided. Specifically, the central axis of the first connection slot 311 does not coincide with the central axis of the second connection slot 314, that is, the central axis of the first connection slot 311 is located beside the second connection slot 314, the central axis of the first connection slot 311 is located above the second connection slot 314, or the central axis of the first connection slot 311 is located below the second connection slot 314. The flexible allocation of the arrangement positions of the first connecting groove 311 and the second connecting groove 314 in this case enables the first connecting groove 311 or the second connecting groove 314 to be arranged at more positions, thereby facilitating the arrangement of the atmosphere lamp assembly 300 at any position of the ultrasonic diagnostic apparatus 10.

The first light emitting element 320 and the first optical fiber 330 are inserted into the first connection tube 310, and referring to fig. 8 and 9, a direction along the first connection groove 311 toward the second connection groove 314 is a first direction, a cross-sectional area of the first connection groove 311 perpendicular to the first direction gradually decreases along the first direction, and the first light emitting element 320 is in interference fit with the first connection groove 311. The arrangement is favorable for the first light emitting element 320 to be inserted into the first connection groove 311, and the cross-sectional area of the first connection groove 311 perpendicular to the first direction is gradually reduced, that is, when the first light emitting element 320 is inserted to a certain distance, because the cross-sectional area of the first connection groove 311 perpendicular to the first direction is gradually reduced, the distance from the inner wall of the first connection groove 311 to the first light emitting element 320 is reduced, and finally the first light emitting element 320 is clamped. The first connection groove 311 and the first light emitting element 320 are arranged in an interference fit manner, and the first connection groove 311 is located in a larger opening arranged at the insertion side of the first light emitting element 320, so that the insertion of the first light emitting element 320 is facilitated, and then the cross-sectional area, perpendicular to the first direction, of the first connection groove 311 is gradually reduced, so that a guiding effect is achieved on the continuous insertion of the first light emitting element 320 partially inserted into the first connection groove 311, and the arrangement facilitates the drawing of the first connection groove 311.

Similarly, the direction along the first connecting slot 311 toward the second connecting slot 314 is a first direction, and in the opposite direction of the first direction, the cross-sectional area of the second connecting slot 314 perpendicular to the first direction gradually decreases, and the first end 331 is in interference fit with the second connecting slot 314. With such an arrangement, it is advantageous for the first optical fiber 330 to be inserted into the second connection groove 314, and the cross-sectional area of the second connection groove 314 perpendicular to the first direction is gradually decreased, so that when the first optical fiber 330 is inserted to a certain distance, since the cross-sectional area of the second connection groove 314 perpendicular to the first direction is gradually decreased, the distance from the inner wall of the second connection groove 314 to the first optical fiber 330 is decreased, and the first optical fiber 330 is finally clamped. The second connecting groove 314 and the first optical fiber 330 are arranged in an interference fit manner, and the second connecting groove 314 is located in a larger opening arranged at the insertion side of the first optical fiber 330, so that the first optical fiber 330 is conveniently inserted, and then the cross-sectional area of the second connecting groove 314, which is perpendicular to the first direction, is gradually reduced, so that the continuous insertion of the first optical fiber 330 partially inserted into the second connecting groove 314 is guided, and the mode drawing of the second connecting groove 314 is convenient.

Of course, it is understood that in other embodiments, specifically, the cross-sectional area of the first connecting slot 311 perpendicular to the first direction is gradually decreased, and the cross-sectional area of the second connecting slot 314 perpendicular to the first direction is gradually decreased along the reverse direction of the first direction.

Referring to fig. 6 to 9, the first connection groove 311 includes a first groove section 312 and a second groove section 313 communicating with the first groove section 312, the second groove section 313 is located at an end of the first connection pipe 310 facing away from the second connection groove 314, and an inner diameter of the second groove section 313 is larger than that of the first groove section 312. The second groove section 313 is used for arranging the connecting portion 321, the first groove section 312 is used for arranging the light emitting portion 322, because the cross-sectional area of the connecting portion 321 is larger than that of the light emitting portion 322 in the direction perpendicular to the axial direction of the first light emitting element 320, and the connecting portion 321 enters the first connecting groove 311 after the light emitting portion 322 as viewed in the direction in which the first light emitting element 320 is inserted into the first connecting groove 311, the first groove section 312 and the second groove section 313 are provided in this way, which satisfies the purpose of reasonably arranging the opening direction according to the position of the first light emitting element 320.

The inner circumference of the second groove section 313 includes a first arc-shaped surface 3131 and a first plane 3132 connected to the first arc-shaped surface 3131, the light emitting element includes a light emitting portion 322 and a connecting portion 321 connected to one end of the light emitting portion 322, the light emitting portion 322 is disposed in the first groove section 312, the connecting portion 321 is disposed in the second groove section 313, the outer circumference of the connecting portion 321 has a second arc-shaped surface and a second plane 3211 connected to the second arc-shaped surface, the second arc-shaped surface abuts against the first arc-shaped surface 3131, and the second plane 3211 abuts against the first plane 3132. The second arc-shaped face is arranged to abut against the first arc-shaped face 3131, so that radial positioning and axial positioning of the first light-emitting element 320 in the first connection slot 311 are achieved, the second arc-shaped face is arranged to abut against the first arc-shaped face 3131, so that circumferential positioning of the first light-emitting element 320 in the first connection slot 311 is achieved, and finally, fixing of the position of the first light-emitting element 320 in the first connection slot 311 is achieved.

The first optical fibers 330 are arranged around the periphery of the control panel 200, the second ends 332 extend to the side of the light emitting elements facing away from the first ends 331, and the second ends 332 are arranged opposite to the first light emitting elements 320 at intervals; alternatively, the first optical fiber 330 is disposed around the outer periphery of the probe cover 112, the second end 332 extends to a side of the light emitting element facing away from the first end 331, and the second end 332 is disposed in spaced opposition to the first light emitting element 320. The arrangement makes the area of the control panel 200 or the probe cover 112 acted by the atmosphere lamp assembly 300 larger, is convenient for the user to operate and observe, and is symmetrical and more beautiful.

It is understood that in other embodiments, the first optical fiber 330 is disposed only on a portion of the outer periphery of the control panel 200 or a portion of the outer periphery of the probe cover 112, and such an arrangement can also illuminate a local position of the control portion or the probe cover 112 and can also serve as a prompt for a user, and such an arrangement is more environmentally friendly.

In order to compensate for the attenuation of the light conducted by the first optical fiber 330 from the first end 331 to the second end 332, the second connection tube 340 and the second light emitting element 350 are introduced in detail according to the foregoing principle. A second connection pipe 340, one end of which is concavely provided with a third connection groove 341 and the other opposite end of which is concavely provided with a fourth connection groove 342, wherein the third connection groove 341 and the fourth connection groove 342 are communicated with each other; the second light emitting element 350 is connected to the third connection groove 341; wherein the second end 332 is connected to the fourth connecting groove 342, and the light emitted from the second light emitting element 350 can enter the second end 332 and be conducted to the first end 331.

Further, a third connection tube, a third light emitting member and a second optical fiber 360 are provided in order to obtain a more uniform and brighter atmosphere lamp effect. One end of the third connecting pipe is concavely provided with a fifth connecting groove, the other end of the third connecting pipe is concavely provided with a sixth connecting groove, and the fifth connecting groove and the sixth connecting groove are communicated with each other; the third light-emitting element is arranged in the fifth connecting groove; a second optical fiber 360 having a third end and a fourth end which are oppositely arranged, the third end is connected to the sixth connecting groove, and light emitted by the third light emitting element can enter the third end and is conducted to the fourth end; wherein the second optical fiber 360 is at least partially arranged at the outer circumference of the control panel 200 or the outer circumference of the probe cover 112.

The second optical fiber 360 and the first optical fiber 330 are arranged around the periphery of the control panel 200, the first light emitting element 320 is arranged opposite to the third light emitting element, and the second end 332 is arranged opposite to the fourth end; alternatively, the second optical fiber 360 and the first optical fiber 330 are arranged together around the outer circumference of the probe cover 112, and the first light emitting element 320 is arranged opposite to the third light emitting element, and the second end 332 is arranged opposite to the fourth end.

Of course, it is understood that in other embodiments, based on the principle described above, specifically, the ultrasonic diagnostic apparatus 10 is provided with multiple sets of the first connecting tube 310, the second connecting tube 340, the first optical fiber 330, the second optical fiber 360, the first light emitting element 320, and the second light emitting element 350 to increase the uniformity of the light emission of the atmosphere lamp, so as to increase the light emission intensity of the atmosphere lamp.

Referring to fig. 13 to 15 and fig. 1, the control panel 200 includes a first plate 210, a first receiving groove 211 extending along a circumferential direction of the first plate 210 is formed on an outer circumference of one side wall of the first plate 210, and the atmosphere lamp assembly 300 is disposed in the first receiving groove 211; the control panel 200 further includes a first transparent cover plate 220, the first transparent cover plate 220 is covered on the notch of the first receiving groove 211; or, a second receiving groove extending along the circumferential direction of the probe cover 112 is formed in the outer circumference of one side wall of the probe cover 112, and the atmosphere lamp assembly 300 is disposed in the second receiving groove; the probe cover 112 further includes a second transparent cover plate 113, and the second transparent cover plate 113 covers the notch of the second receiving groove.

The receiving groove is provided to fix the positions of the first optical fiber 330 and the first light emitting element 320, and the transparent plate is provided to allow the light emitted from the first optical fiber 330 disposed inside the first plate body 210 or the probe cover 112 to be viewed by a user.

It should be noted that, the first holding groove 211, the second holding groove, the depth of third holding groove 221 and fourth holding groove 1131 is decided according to the actual demand, can set up darker first holding groove 211, the second holding groove, the all wall face that more first optic fibre 330 was come to the laminating of third holding groove 221 and fourth holding groove 1131, thereby realize more stable fixed to first optic fibre 330, also can set up shallower first holding groove 211 for reducing the occupation to other component positions of ultrasonic diagnostic apparatus 10, the second holding groove, third holding groove 221 and fourth holding groove 1131, it can only to need the holding groove that satisfies the setting can fix first optic fibre 330.

Further, in order to more firmly position the first optical fiber 330 in the accommodating groove, a rib is provided in the accommodating groove of the original accommodating groove and the first light-transmitting cover plate 220, referring to fig. 14 and 15, specifically, the control panel 200 includes a first plate 210, a first accommodating groove 211 extending along the circumferential direction of the first plate 210 is provided at the periphery of one side wall of the first plate 210, the atmosphere lamp assembly 300 is provided in the first accommodating groove 211, the control panel 200 further includes the first light-transmitting cover plate 220, and the first light-transmitting cover plate 220 is covered at the notch position of the first accommodating groove 211; the wall surface of the first light-transmitting cover plate 220 facing the first accommodating groove 211 is provided with a third accommodating groove 221, the third accommodating groove 221 and the first accommodating groove 211 jointly form a first accommodating cavity for accommodating the first optical fiber 330, the first light-transmitting cover plate 220 is provided with a first rib plate 222, the first rib plate 222 abuts against the wall surface of the first connecting pipe 310, the first accommodating groove 211 is internally provided with a second rib plate 212, and the second rib plate 212 abuts against the wall surface of the first connecting pipe 310; or, a second accommodating groove extending along the circumferential direction of the probe cover 112 is formed in the periphery of one side wall of the probe cover 112, the atmosphere lamp assembly 300 is arranged in the second accommodating groove, the probe cover 112 further comprises a second transparent cover plate 113, and the second transparent cover plate 113 is arranged at the notch position of the second accommodating groove in a covering manner; second printing opacity apron 113 is equipped with fourth holding tank 1131 towards the wall of second holding tank, and fourth holding tank 1131 and second holding tank constitute the second that holds first optic fibre 330 jointly and hold the chamber, and second printing opacity apron 113 is equipped with third gusset 1132, and third gusset 1132 butt first connecting pipe 310's wall is equipped with the fourth gusset in the second holding tank, and the fourth gusset butt first connecting pipe 310's wall.

Set up the fixed first optic fibre 330 of gusset aim at in the cavity between holding tank and printing opacity apron, according to this purpose, crisscross setting about the gusset can be controlled, the gusset can be along the setting of an orientation of holding tank, the gusset can be partly be located one side part of holding tank and be located the holding tank opposite side, of course, the shape of gusset and the intensive degree that the gusset was arranged, as long as aim at is fixed first optic fibre 330 in the cavity between holding tank and printing opacity apron, are the utility model discloses an original intention.

In summary, it can be understood that the rib plate can be disposed in the receiving groove to abut against the first connecting pipe 310 to fix the first connecting pipe 310. Because the surface that first connecting pipe 310 was is the curved surface, area of contact during the butt is less, and the effort of butt is unstable, so the technical scheme of the utility model in the position that first connecting pipe 310 is used for the butt set up the plane. Referring to fig. 5, 6 and 14, the third plane 316 and the fourth plane 317 are planes for abutting on the first connecting tube 310, specifically, the control panel 200 includes the first plate 210, a first receiving groove 211 extending along the periphery of the first plate 210 is disposed on the periphery of one side wall of the first plate 210, the atmosphere lamp assembly 300 is disposed in the first receiving groove 211, the control panel 200 further includes the first light-transmitting cover plate 220, the first light-transmitting cover plate 220 is covered on the notch position of the first receiving groove 211, a third receiving groove 221 is disposed on the wall surface of the first light-transmitting cover plate 220 facing the first receiving groove 211, the third receiving groove 221 and the first receiving groove 211 jointly form a first receiving cavity for receiving the atmosphere lamp assembly 300, the first light-transmitting cover plate 220 is provided with a first rib plate 222, the first rib plate 222 abuts against the wall surface of one side of the first connecting tube 310 facing the first light-transmitting cover plate 220, a second rib plate 212 is disposed in the first receiving groove 211, and the second rib plate 212 abuts against the wall surface of one side of the first connecting tube 310 facing away from the periphery of the first connecting tube 210. A third plane 316 is arranged on a side of the first connecting pipe 310 away from the first plate 210, and the first rib plate 222 abuts against the third plane 316.

Continuing to refer to fig. 5, 6 and 14, a second accommodating groove extending along the periphery of the probe cover 112 is arranged at the periphery of one side wall of the probe cover 112, the atmosphere lamp assembly 300 is arranged in the second accommodating groove, the probe cover 112 further comprises a second transparent cover plate 113, the second transparent cover plate 113 is arranged at the position of a notch of the second accommodating groove in a covering manner, a fourth accommodating groove 1131 is arranged on the wall surface of the second transparent cover plate 113 facing the second accommodating groove, the fourth accommodating groove 1131 and the second accommodating groove jointly form a second accommodating cavity for accommodating the atmosphere lamp assembly 300, the second transparent cover plate 113 is provided with a third rib plate 1132, the third rib plate 1132 is abutted against the wall surface of one side of the first connecting pipe 310 facing the second transparent cover plate 113, a fourth rib plate is arranged in the second accommodating groove, and the fourth rib plate is abutted against the wall surface of one side of the first connecting pipe 310 facing away from the periphery of the probe cover 112; one side of the first connecting tube 310 facing the second transparent cover plate 113 is provided with a fourth plane 317, and the first rib 222 abuts against the fourth plane 317.

The third plane 316 and the fourth plane 317 are arranged, so that the first connecting pipe 310 has a larger action area when the rib plates are abutted, and the stability of fixing the first connecting pipe 310 is further improved.

Correspondingly, the embodiment of the present invention further provides an ultrasonic diagnostic apparatus 10, which includes a display 700, a control panel 200 and a host 100. The control panel 200 and the display 700 are electrically connected to the host 100, respectively, the host 100 includes a host housing 110, a socket 800 and an atmosphere lamp assembly 300, the socket 800 is connected to the host housing 110, the socket 800 is used for electrically connecting the probe 130, and the atmosphere lamp assembly 300 includes: a first connection pipe 310 having a first connection groove 311 concavely formed at one end thereof and a second connection groove 314 concavely formed at the opposite end thereof, the first connection groove 311 and the second connection groove 314 being communicated with each other; a first light emitting element 320 provided in the first connection groove 311; the first optical fiber 330 has a first end 331 and a second end 332 opposite to each other, the first end 331 is connected to the second connecting groove 314, the light emitted from the first light emitting element 320 can enter the first end 331 and be transmitted to the second end 332, wherein the ultrasonic diagnostic apparatus 10 includes a first plate 210 and a second plate, the first plate 210 is connected to the second plate, an exposed seam is formed between the first plate 210 and the second plate, and at least a part of the first optical fiber 330 is disposed at the seam.

The arrangement of the splicing form is arranged, so that the arrangement of optical fibers is facilitated, the better luminous intensity of the atmosphere lamp is achieved on the premise of saving consumables, and the atmosphere lamp is arranged in a more appropriate position.

In the present embodiment, in particular, the improvement of the ultrasonic diagnostic apparatus 10 has the same technical effects as the above-described ultrasonic diagnostic apparatus 10, and the details are not described here.

The utility model also provides an atmosphere banks spare 300 that sets up in above-mentioned ultrasonic diagnostic instrument 10, this atmosphere banks spare 300 includes first connecting pipe 310, first light emitting component 320 and first optic fibre 330. The first connection pipe 310 has a first connection groove 311 recessed at one end thereof and a second connection groove 314 recessed at the opposite end thereof, and the first connection groove 311 and the second connection groove 314 are communicated with each other. The first light emitting element 320 is connected to the first connection groove 311. A first optical fiber 330 having a first end 331 and a second end 332 opposite to each other, the first end 331 is connected to the second connecting groove 314, and light emitted from the first light emitting element 320 can enter the first end 331 and be conducted to the second end 332. Wherein the first optical fiber 330 is at least partially used to be arranged at the periphery of the control panel 200 of the ultrasonic diagnostic apparatus 10 or the periphery of the probe cover 112 of the ultrasonic diagnostic apparatus 10.

The utility model provides an atmosphere banks spare 300, the light that first light emitting component 320 sent follow first optic fibre 330's length direction after entering first optic fibre 330's first end 331 propagates to first optic fibre 330's second end 332, adopts first optic fibre 330 to show to be rectangular form light band effect in this scheme promptly. Compared with the technical scheme that the light band effect is displayed by a plurality of linearly arranged lamp beads in the prior art, the light emitted by the first light-emitting element 320 cannot directly irradiate the eyes of the user, so that the comfort of the user in observing the atmosphere lamp is improved. Moreover, the first optical fiber 330 is used for transmitting light, so that the light emitting effect is softer and more uniform.

It should be noted that, other contents of the ultrasonic diagnostic apparatus 10 and the atmosphere lamp assembly 300 according to the present disclosure can be referred to the atmosphere lamp assembly 300 in the ultrasonic diagnostic apparatus 10 in the foregoing embodiments, and the details are not repeated herein.

The above is only the preferred embodiment of the present invention, not so limiting the patent scope of the present invention, all of which are in the utility model discloses a conceive, utilize the equivalent structure transform that the content of the specification and the attached drawings did, or directly/indirectly use all to include in other relevant technical fields the patent protection scope of the present invention.

Claims (15)

1. An atmospheric lamp assembly for an ultrasonic diagnostic apparatus, comprising:

one end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other;

a first light emitting element connected to the first connection groove;

a first optical fiber having a first end and a second end opposite to each other, the first end being connected to the second connection groove, light emitted from the first light emitting element being capable of entering the first end and being conducted to the second end;

wherein the first optical fiber is at least partially arranged on the periphery of a control panel of the ultrasonic diagnostic apparatus or the periphery covered by a probe of the ultrasonic diagnostic apparatus.

2. The utility model provides an ultrasonic diagnostic apparatus, includes display, control panel and host computer, the display and control panel electricity respectively connect in the host computer, the host computer includes mainframe shell, socket and atmosphere banks spare, the mainframe shell include the shell main part and with the probe of the detachable connection of shell main part covers, the socket connect in the shell main part, the socket is used for the electricity to connect the probe, the probe covers the cover the socket, its characterized in that, the atmosphere banks spare includes:

one end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other;

a first light emitting element connected to the first connection groove;

a first optical fiber having a first end and a second end opposite to each other, the first end being connected to the second connection groove, light emitted from the first light emitting element being capable of entering the first end and being conducted to the second end;

wherein the first optical fiber is at least partially disposed at an outer periphery of the control panel or an outer periphery of the probe cover.

3. The ultrasonic diagnostic apparatus according to claim 2,

an end face of the first end is spaced apart from the first light emitting element.

4. The ultrasonic diagnostic apparatus according to claim 2,

the first connecting pipe is internally provided with an annular bulge between the first connecting groove and the second connecting groove, the inner through hole of the annular bulge is respectively communicated with the first connecting groove and the second connecting groove, the annular bulge is provided with an annular end face deviating from the first light-emitting element, and the annular end face abuts against the end face of the first end facing the first light-emitting element.

5. The ultrasonic diagnostic apparatus according to claim 2,

the central axis of the first connecting groove coincides with the central axis of the second connecting groove.

6. The ultrasonic diagnostic apparatus according to claim 2,

the direction pointing to the second connecting groove along the first connecting groove is a first direction, the cross-sectional area of the first connecting groove perpendicular to the first direction is gradually reduced along the first direction, and the first light-emitting element is in interference fit with the first connecting groove;

and/or the presence of a gas in the gas,

the direction of following first spread groove directional second spread groove is first direction, follows the reverse of first direction, the perpendicular to of second spread groove the cross sectional area of first direction reduces gradually, first end with second spread groove interference fit.

7. The ultrasonic diagnostic apparatus according to claim 2,

the first connecting groove comprises a first groove section and a second groove section communicated with the first groove section, the second groove section is positioned at the end part of the first connecting pipe departing from the second connecting groove, the inner diameter of the second groove section is larger than that of the first groove section, the inner periphery of the second groove section comprises a first arc-shaped surface and a first plane connected with the first arc-shaped surface,

the light-emitting component comprises a light-emitting part and a connecting part connected to one end of the light-emitting part, the light-emitting part is arranged on the first groove section, the connecting part is arranged on the second groove section, the periphery of the connecting part is provided with a second arc-shaped surface and a second plane connected with the second arc-shaped surface, the second arc-shaped surface is abutted to the first arc-shaped surface, and the second plane is abutted to the first plane.

8. The ultrasonic diagnostic apparatus according to claim 2,

the first optical fibers are arranged around the periphery of the control panel, the second ends extend to the side, facing away from the first ends, of the light-emitting elements, and the second ends are arranged opposite to the first light-emitting elements at intervals;

or the like, or, alternatively,

the first optical fiber is arranged around the periphery of the probe cover, the second end extends to the side of the light-emitting element, which is far away from the first end, and the second end and the first light-emitting element are oppositely arranged at intervals.

9. The ultrasonic diagnostic apparatus according to claim 2 or 8, wherein the atmosphere lamp assembly further comprises:

one end of the second connecting pipe is concavely provided with a third connecting groove, the other end of the second connecting pipe is concavely provided with a fourth connecting groove, and the third connecting groove and the fourth connecting groove are communicated with each other;

a second light emitting element connected to the third connection groove;

wherein the second end is connected to the fourth connection groove, and light emitted from the second light emitting element can enter the second end and be conducted to the first end.

10. The ultrasonic diagnostic apparatus of claim 2, wherein the atmosphere lamp assembly further comprises:

one end of the third connecting pipe is concavely provided with a fifth connecting groove, the other end of the third connecting pipe is concavely provided with a sixth connecting groove, and the fifth connecting groove and the sixth connecting groove are communicated with each other;

a third light emitting element provided in the fifth connection groove;

a second optical fiber having a third end and a fourth end which are oppositely arranged, the third end is connected to the sixth connection groove, and the light emitted by the third light-emitting element can enter the third end and is conducted to the fourth end;

wherein the second optical fiber is at least partially disposed at an outer periphery of the control panel or an outer periphery of the probe cover.

11. The ultrasonic diagnostic apparatus according to claim 10,

the second optical fiber and the first optical fiber are arranged around the periphery of the control panel together, the first light-emitting element and the third light-emitting element are arranged oppositely, and the second end and the fourth end are arranged oppositely;

or the like, or, alternatively,

the second optical fiber and the first optical fiber are arranged around the periphery of the probe cover together, the first light-emitting element and the third light-emitting element are arranged oppositely, and the second end and the fourth end are arranged oppositely.

12. The ultrasonic diagnostic apparatus according to claim 2,

the control panel comprises a first plate body, a first accommodating groove extending along the circumferential direction of the first plate body is formed in the periphery of one side wall of the first plate body, and the atmosphere lamp assembly is arranged in the first accommodating groove; the control panel further comprises a first light-transmitting cover plate, and the first light-transmitting cover plate is arranged at the notch position of the first accommodating groove in a covering mode;

or the like, or, alternatively,

a second accommodating groove extending along the circumferential direction of the probe cover is formed in the periphery of one side wall of the probe cover, and the atmosphere lamp assembly is arranged in the second accommodating groove; the probe covers still includes the second printing opacity apron, second printing opacity apron lid is located the notch position of second holding tank.

13. The ultrasonic diagnostic apparatus according to claim 2,

the control panel comprises a first plate body, a first accommodating groove extending along the circumferential direction of the first plate body is formed in the periphery of one side wall of the first plate body, the atmosphere lamp assembly is arranged in the first accommodating groove, the control panel further comprises a first light-transmitting cover plate, and the first light-transmitting cover plate is arranged at the position of a notch of the first accommodating groove in a covering mode; a third accommodating groove is formed in the wall surface, facing the first accommodating groove, of the first light-transmitting cover plate, the third accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the first optical fiber, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate is abutted to the wall surface of the first connecting pipe, a second rib plate is arranged in the first accommodating groove, and the second rib plate is abutted to the wall surface of the first connecting pipe;

or the like, or, alternatively,

the periphery of one side wall of the probe cover is provided with a second accommodating groove extending along the circumferential direction of the probe cover, the atmosphere lamp assembly is arranged in the second accommodating groove, the probe cover further comprises a second light-transmitting cover plate, and the second light-transmitting cover plate is covered at the notch position of the second accommodating groove; the second light-transmitting cover plate is provided with a fourth accommodating groove facing the wall surface of the second accommodating groove, the fourth accommodating groove and the second accommodating groove jointly form a second accommodating cavity for accommodating the first optical fiber, the second light-transmitting cover plate is provided with a third rib plate, the third rib plate is abutted to the wall surface of the first connecting pipe, a fourth rib plate is arranged in the second accommodating groove, and the fourth rib plate is abutted to the wall surface of the first connecting pipe.

14. The ultrasonic diagnostic apparatus according to claim 2,

the control panel comprises a first plate body, a first accommodating groove extending along the periphery of the first plate body is formed in the periphery of one side wall of the first plate body, the atmosphere lamp assembly is arranged in the first accommodating groove, the control panel further comprises a first light-transmitting cover plate, the first light-transmitting cover plate is arranged at the notch position of the first accommodating groove in a covering mode, a third accommodating groove is formed in the wall surface, facing the first accommodating groove, of the first light-transmitting cover plate, the third accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the atmosphere lamp assembly, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate abuts against the wall surface, facing one side of the first light-transmitting cover plate, of the first connecting pipe, a second rib plate is arranged in the first accommodating groove, and the second rib plate abuts against the wall surface, facing away from one side of the periphery of the first connecting pipe; a third plane is arranged on one side, away from the first plate body, of the first connecting pipe, and the first rib plate abuts against the third plane;

or the like, or a combination thereof,

the periphery of one side wall of the probe cover is provided with a second accommodating groove extending along the periphery of the probe cover, the atmosphere lamp assembly is arranged in the second accommodating groove, the probe cover further comprises a second light-transmitting cover plate, the second light-transmitting cover plate is arranged at the position of a groove opening of the second accommodating groove in a covering mode, a fourth accommodating groove is arranged on the wall surface, facing the second accommodating groove, of the second light-transmitting cover plate, the fourth accommodating groove and the second accommodating groove jointly form a second accommodating cavity for accommodating the atmosphere lamp assembly, the second light-transmitting cover plate is provided with a third rib plate, the third rib plate abuts against the wall surface, facing one side of the first connecting pipe to the second light-transmitting cover plate, a fourth rib plate is arranged in the second accommodating groove, and the fourth rib plate abuts against the wall surface, facing away from the periphery of the probe cover, of the first connecting pipe; and a fourth plane is arranged on one side of the first connecting pipe facing the second light-transmitting cover plate, and the first rib plate is abutted against the fourth plane.

15. The utility model provides an ultrasonic diagnostic apparatus, includes display, control panel and host computer, control panel and the display electricity respectively connect in the host computer, the host computer includes mainframe shell, socket and atmosphere banks spare, the socket connect in the mainframe shell, the socket is used for the electricity to connect the probe, its characterized in that, the atmosphere banks spare includes:

one end of the first connecting pipe is concavely provided with a first connecting groove, the other end of the first connecting pipe is concavely provided with a second connecting groove, and the first connecting groove and the second connecting groove are communicated with each other;

the first light-emitting element is arranged in the first connecting groove;

a first optical fiber having a first end and a second end opposite to each other, the first end being connected to the second connection groove, light emitted from the first light emitting element being capable of entering the first end and being conducted to the second end;

the ultrasonic diagnostic apparatus comprises a first plate body and a second plate body, wherein the first plate body is connected with the second plate body, an exposed seam is formed between the first plate body and the second plate body, and at least part of the first optical fiber is arranged at the seam.

Images