CN115869008A - Desktop ultrasound device - Google Patents

Abstract

The invention relates to the technical field of medical instruments, in particular to a table type ultrasonic device, which comprises a base; a host; the host computer includes: the front-end module is integrally spaced from the rear-end module, the front-end module is packaged in a first case, the rear-end module is packaged in a second case, the second case is independent of the first case, the front-end module is provided with a first connector, the rear-end module comprises a rear-end data computing processing board and a switching board which are electrically connected with each other, and the switching board is provided with a second connector; and two ends of the shielding cable are respectively connected with the first connector and the second connector, and the front-end module and the rear-end module are connected through the shielding cable to realize signal transmission. Through setting up front end module and rear end module looks interval, and the two branch locates mutually independent first quick-witted case and second quick-witted incasement to utilize the shielded cable to realize signal transmission, reduced transmission loss and signal interference between front end module and the rear end module, ensured ultrasonic equipment's use reliability.

Description

Desktop ultrasound device

Technical Field

The invention relates to the technical field of medical instruments, in particular to a table type ultrasonic device.

Background

In recent years, ultrasonic examination has become one of the main auxiliary means for diagnosis of doctors due to its characteristics of safety, convenience, no damage, low price, etc. Desktop ultrasound equipment is increasingly tending to be miniaturized, has the characteristics of convenient movement and transportation, and is particularly suitable for being applied in crowded environments of hospitals. The body part of the desk type ultrasonic equipment generally comprises a probe board, a probe transmitting and receiving signal board, a system board, a data processing board, a power supply board and the like, the layout of the board cards is complex, the modularization degree is low, and signal transmission is easy to interfere.

Disclosure of Invention

One object of the present invention is to solve the disadvantages of the prior art and to provide a desktop ultrasound device with a reasonable layout and less signal interference.

In order to solve the technical problem, the invention adopts the following technical scheme:

a tabletop ultrasound device comprising:

a base;

the host computer, the setting is on the base, and the host computer includes: the front-end module is integrally spaced from the rear-end module, the front-end module is packaged in a first case, the rear-end module is packaged in a second case, the second case is independent of the first case, the front-end module is provided with a first connector, the rear-end module comprises a rear-end data computing processing board and a switching board which are electrically connected with each other, and the switching board is provided with a second connector; and

and one end of the shielding cable is connected with the first connector, the other end of the shielding cable is connected with the second connector, and the front-end module and the rear-end module are connected through the shielding cable to realize signal transmission.

In one embodiment, the first case and the second case are both arranged on the base in a vertical state.

In one embodiment, the desktop ultrasound device further comprises a power module disposed within the second housing.

In one embodiment, the desktop ultrasound device further comprises a power module disposed at the bottom of the base, the power module being enclosed in a third enclosure, the power module being spaced apart from the front end module and the back end module by the base.

In one embodiment, the table-top ultrasound device further comprises:

the lower end of the support column downwards extends into the host, the bottom end of the support column is fixed on the base, the support column extending into the host is arranged between the front end module and the rear end module at intervals, the upper end of the support column upwards extends out of the host, the first case and the second case are arranged at intervals, an interval space is formed between the first case and the second case, and the support column is arranged at the interval space; and

and the control panel is arranged at the part of the support column extending out of the host.

In one embodiment, the support column is a liftable support column, and the support column includes: outer column and the inner column of setting in outer column, inner column can rise and descend for outer column, and control panel sets up the top at inner column.

In one embodiment, the front-end module comprises a probe board and an ultrasonic front-end signal processing board which are electrically connected with each other, a probe interface for plugging a probe is arranged on the probe board, the first connector is arranged on the ultrasonic front-end signal processing board, the probe board and the ultrasonic front-end signal processing board are both arranged perpendicular to the base, and the probe board is parallel to the ultrasonic front-end signal processing board.

In one embodiment, a first socket is arranged on the probe board, a second socket is arranged on the ultrasonic front-end signal processing board corresponding to the first socket, and the first socket and the second socket can be relatively plugged and adapted, so that the probe board and the ultrasonic front-end signal processing board are electrically connected.

In one embodiment, the back-end data calculation processing board is arranged perpendicular to the base, and the adapter board is vertically connected to the back-end data calculation processing board.

In one embodiment, a third socket is arranged on the back-end data calculation processing board, a fourth socket is arranged on the adapter board corresponding to the third socket, and the third socket and the fourth socket can be correspondingly plugged and adapted.

In one embodiment, the back-end module further comprises a display card, the display card is electrically connected with the back-end data calculation processing board, the display card is vertically connected to the back-end data calculation processing board, and the display card is arranged in parallel and at intervals relative to the adapter plate.

In one embodiment, a fifth interface is arranged on the back-end data calculation processing board, a sixth interface is arranged on the graphics card corresponding to the fifth interface, and the fifth interface and the sixth interface can be relatively plugged and adapted.

In one embodiment, the back-end module further includes a peripheral interface board electrically connected to the back-end data calculation processing board, the peripheral interface board is provided with a plurality of interfaces for connecting external devices, the peripheral interface board is vertically connected to the back-end data calculation processing board, and the peripheral interface board is arranged in parallel and spaced apart from the adapter board.

According to the technical scheme, the invention has at least the following advantages and positive effects:

according to the invention, the front end module and the rear end module of the host are arranged at intervals, the front end module and the rear end module are respectively arranged in the first case and the second case which are mutually independent, and the signal transmission is realized between the front end module and the rear end module by using the shielding cable, so that the ultrasonic function of the ultrasonic equipment is modularized, the transmission loss and the signal interference between the front end module and the rear end module are reduced, the independent operation and the heat dissipation of each module are facilitated, the mutual influence is reduced, and the use reliability of the ultrasonic equipment is effectively ensured.

Drawings

FIG. 1 is a schematic structural diagram of a desktop ultrasound device according to an embodiment of the present invention;

FIG. 2 is a first schematic structural diagram of the traveling mechanism and the host machine of the structure shown in FIG. 1;

FIG. 3 is a second schematic structural view of the traveling mechanism and the host machine of the structure shown in FIG. 1;

FIG. 4 is a schematic block diagram of a front end module of the configuration shown in FIG. 2;

fig. 5 is a schematic diagram of the back end module of the structure shown in fig. 2.

The reference numerals are illustrated below:

10-a traveling mechanism; 20-a host; 30-a support column; 40-a control panel; 50-a display device;

100-a base;

200-a first chassis;

300-front end module;

310-a probe plate; 311-probe interface;

320-ultrasonic front end signal processing board; 321-a second interface;

400-a second chassis;

500-a back end module;

510-a back-end data computation processing board; 520-an adapter plate;

530-display card;

600-shielded cables;

700-a third chassis;

800-power module.

Detailed Description

Exemplary embodiments that embody features and advantages of the invention are described in detail below in the specification. It is understood that the invention is capable of other and different embodiments and its several details are capable of modification in various other respects, all without departing from the scope of the present invention, and that the description and drawings are to be taken as illustrative and not restrictive in character.

In the description of the present application, it is to be understood that the indications of directions or positional relationships (such as up, down, left, right, front, rear, and the like) in the embodiments shown in the drawings are merely for convenience of description and simplicity of description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated. These descriptions are appropriate when the elements are in the positions shown in the drawings. If the description of the positions of these elements changes, the indication of these directions changes accordingly.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

The desktop ultrasound apparatus will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1 and 2, the desktop ultrasound apparatus of the present invention includes a traveling mechanism 10, a main unit 20 disposed above the traveling mechanism 10, a control panel 40 disposed on the main unit 20, and a display device 50 disposed on the control panel 40.

The running gear 10 includes a base 100 and a roller provided at the bottom of the base 100, and the roller may have a locking function, so that the ultrasonic apparatus may be moved to a desired position as desired, and the ultrasonic apparatus may be locked at a current position when moved to the desired position.

The control panel 40 is disposed above the host 20, and the control panel 40 is supported and connected to the base 100 by a supporting column 30. The control panel 40 is provided with various operation keys, for example: trackball keys, 3D keys, contrast keys, image/video capture keys, image analysis adjustment keys, and the like. The doctor can select any key or combine a plurality of keys according to the control requirement to control the probe input and detection of the ultrasonic equipment, or control the image or video display and the like.

The display device 50 is mainly used for displaying information such as: two-dimensional, three-dimensional, four-dimensional images, video or sound, etc. Display device 50 is typically mounted on control panel 40 to be synchronized with control panel 40 for hands-eye consistent operation by the healthcare operator.

The main unit 20 is disposed on the base 100, and the main unit 20 includes a front end module 300 and a rear end module 500, and a power supply module 800 for supplying power. According to the conventional practice of signal classification by those skilled in the art, the received unprocessed external signal is defined as a front-end signal, and the processed generated secondary signal is defined as back-end data, so in the present application, the front-end module 300 is used for receiving an external analog signal and performing wave number synthesis, and specifically, the front-end module 300 is a module integrating the transmitting, receiving and signal synthesizing functions of an ultrasound system; the back-end module 500 is used for receiving and processing the secondary signals output after being processed by the front-end module 300, i.e. the signals obtained by synthesizing the wave numbers are subjected to image signal processing, and specifically, the back-end module 500 is substantially equivalent to a computer module which can perform data calculation, graphic display, input and output, and the like. The power module 800 is used for providing power for the whole machine.

Referring to fig. 2, in the desktop ultrasound device according to the embodiment of the present invention, the front module 300 is integrally spaced apart from the rear module 500, the front module 300 is enclosed in the first chassis 200, the rear module 500 is enclosed in the second chassis 400, and the second chassis 400 is independent from the first chassis 200. The front module 300 is provided with a first connector, the rear module 500 comprises a rear data calculation processing board 510 and a patch board 520 which are electrically connected with each other, a second connector is arranged on the patch board 520, and the first connector and the second connector are connected by a shielding cable 600, so that signal transmission is realized by connecting the front module 300 and the rear module 500 through the shielding cable 600.

Through the front end module 300 with host computer 20 and rear end module 500 looks interval setting, and utilize shielded cable 600 to realize signal transmission between front end module 300 and the rear end module 500, reduced transmission loss and signal interference between front end module 300 and the rear end module 500, effectively ensured ultrasonic equipment's use reliability. By respectively arranging the front-end module 300 and the rear-end module 500 in the first case 200 and the second case 400 which are independent of each other, the signal interference between the front-end module 300 and the rear-end module 500 is further reduced, the modularization of the ultrasonic function of the ultrasonic equipment is facilitated, the independent operation and heat dissipation of each module are facilitated, the influence between each other is reduced, and the subsequent maintenance and repair are facilitated.

The shielded cable 600 in the present application may be, but is not limited to, one or more MINI-SAS or SFP high-speed shielded cables, and is characterized in that it needs to satisfy the requirements of anti-interference capability, versatility and scalability of communication protocol, and design and be compatible with multiple signal bandwidths. The shielding cable 600 is matched with the first connector arranged on the front-end module 300 and the second connector arranged on the adapter plate 520, so that high-definition rapid signal transmission is ensured, and the quality of signal transmission is ensured not to be interfered.

According to the supporting column 30 of the embodiment of the application, the lower end of the supporting column 30 extends downwards into the host 20 and the bottom end of the supporting column 30 is fixed on the base 100, the supporting column 30 extending into the host 20 is spaced between the front end module 300 and the rear end module 500, the upper end of the supporting column 30 extends upwards out of the host 20, and the control panel 40 is installed at the position where the supporting column 30 extends out of the host 20. The supporting column 30 is arranged between the front end module 300 and the rear end module 500 at the interval of the part extending into the main machine 20, so that the signal interference between the front end module 300 and the rear end module 500 is further shielded, and the use reliability of the ultrasonic equipment is effectively guaranteed.

Preferably, the first housing 200 is spaced apart from the second housing 400 to form a space therebetween, and the supporting pillars 30 are installed at the space. By respectively arranging the front-end module 300 and the rear-end module 500 in the first case 200 and the second case 400 which are independent of each other, not only is the signal interference between the front-end module 300 and the rear-end module 500 further reduced, but also the modularization of the ultrasonic function of the ultrasonic equipment is facilitated, and the subsequent maintenance and repair are facilitated. In addition, by arranging the supporting posts 30 at the spaced spaces, it is possible to shield signal interference between the front-end module 300 and the rear-end module 500 on the one hand, and to facilitate reasonable layout of the main body 20 and the supporting posts 30 and other components of the ultrasonic apparatus on the other hand, thereby reducing the overall area of the ultrasonic apparatus.

Support column 30 is the liftable formula support column, and support column 30 includes: an outer column and an inner column disposed inside the outer column, the inner column being capable of ascending and descending relative to the outer column, the control panel 40 being disposed at the top end of the inner column. In this embodiment, the supporting columns 30 are liftable supporting columns, and the supporting columns 30 are disposed at the space between the first chassis 200 and the second chassis 400.

The lower end of the supporting column 30 extends into the main frame 20, so that the main frame 20 provides a receiving space for the supporting column 30, the height of the outer column is ensured, and the inner column has a sufficient lifting space, thereby expanding the limit range of lifting of the control panel 40, and the control panel 40 can be lowered to be equal to the height of the main frame 20 at the lowest and can be raised to reach the double height of the main frame 20 at the highest (assuming that the inner and outer columns are equal to the main frame, the lowered limit position of the inner column does not exceed the main frame 20, and the raised limit height of the inner column is the added height of the inner and outer columns). Thereby when ultrasonic equipment transports, can reduce ultrasonic equipment to the minimum through support column 30 to reduce the complete machine focus, stability and security when guaranteeing the complete machine transportation reduce the machine loss rate of long distance transportation, also reduced the cost of packing transportation simultaneously, make ultrasonic equipment can satisfy air transport's demand easily, and when carrying out the bulk cargo transportation of individual machine, also can adorn and transport in little freight train, cost of transportation greatly reduced.

In addition, when the ultrasonic equipment is used, the use requirements of some special scenes can be better met by expanding the limit range of the lifting of the control panel 40, and the use comfort of medical care operators is improved. Such as: when using ultrasonic equipment between the operation, usable over-and-under type's support column 30 rises control panel 40 to the highest point, makes medical care operator when operating with the posture of standing, need not switch the position just can operate ultrasonic equipment simultaneously, avoids frequently bending back and frequently standing again when operating ultrasonic equipment and operates, is showing the working strength who has reduced medical care operator. In addition, when a medical operator performs ultrasonic examination of a certain special body position, for example, ultrasonic examination of ankle position, a patient needs to be examined in a standing posture, and a doctor needs to operate a probe of an ultrasonic apparatus in a squatting posture. When the control panel 40 is lowered by the lifting support column 30, the doctor can operate the probe with one hand at the squatting position and operate the control panel 40 with the other hand, so that the user can avoid squatting for a moment to operate the probe and stand up for a moment to operate the control panel.

In the present application, the first chassis 200 and the second chassis 400 are both disposed on the base 100 in an upright state. It is understood that the vertical state arrangement means that the height directions of the first chassis 200 and the second chassis 400 are both in the vertical direction. The first case 200 and the second case 400 are arranged on the base 100 in a vertical state, so that the overall area of the part of the host 20 is reduced on one hand, and on the other hand, the overall height of the host 20 is basically consistent with that of the first case 200 and the second case 400, namely, the overall height of the host 20 is not higher than that of the first case 200 and the second case 400, so that the overall height of the ultrasonic equipment can be ensured within a reasonable lower range, the stability and safety during overall transportation are improved, and the packing and transporting cost is reduced.

The first chassis 200 and the second chassis 400 may be oppositely and alternately arranged on the base 100, and the supporting columns 30 are located in the space between the first chassis 200 and the second chassis 400. It should be noted that the front side is the side close to the medical operator, the back side is the side far from the medical operator, and the other two sides can be called as the left side and the right side. In an embodiment, the first chassis 200 and the second chassis 400 may be spaced apart front to back. In other embodiments, the first chassis 200 and the second chassis 400 may be arranged at a left-right interval.

Alternatively, the first chassis 200 and the second chassis 400 may be disposed on the base 100 at an angle, and the supporting posts 30 are located in the space between the first chassis 200 and the second chassis 400. For example, the first chassis 200 and the second chassis 400 may be substantially L-shaped distributed on the base 100.

According to one embodiment of the present invention, the power module 800 is disposed at the bottom of the base 100, the power module 800 is enclosed in the third housing 700, and the power module 800 is spaced apart from the front end module 300 and the rear end module 500 by the base 100. The power module of the present embodiment is disposed in the third chassis 700 below the base 100, and is separated by the base 100 with respect to the front end module 300 and the rear end module 500, thereby reducing interference of the power module 800 with the front end module 300 and/or the rear end module 500. In addition, the power module 800 is arranged at the bottom of the base 100, so that the gravity center of the whole machine can be lowered to a certain extent, and the stability and the safety of the whole machine during transportation are improved.

In other embodiments, the power module 800 may be disposed in the second housing 400, so that the distributed layout of the hosts 20 may be reduced, and the structural arrangement of the hosts 20 may be more compact.

The power module 800 may include a battery, a power circuit board, a filter circuit module, a power conversion module, and a power input interface. The power module 800 is a power supply center of the entire desktop ultrasound apparatus, is connected to an external socket through a power input interface, and supplies power to each module in the main unit 2, the control panel 40, the display device 50, and the like through ac-dc conversion and voltage transformation.

Referring to fig. 2 and 4, the front-end module 300 may include a probe board 310 and an ultrasonic front-end signal processing board 320 electrically connected to each other, the probe board 310 and the ultrasonic front-end signal processing board 320 are both arranged perpendicular to the base 100, the probe board 310 is parallel to the ultrasonic front-end signal processing board 320, and the first connector is disposed on the ultrasonic front-end signal processing board 320. In this embodiment, the probe board 310 is parallel to the ultrasonic front-end signal processing board 320, and the probe board and the ultrasonic front-end signal processing board are vertically disposed, so as to reduce the thickness of the first chassis 200 to the maximum extent, facilitate reducing the floor area of the whole machine, and improve the structural compactness of the whole machine.

The probe plate 310 is provided with a first socket, the ultrasonic front-end signal processing plate 320 is provided with a second socket 321 corresponding to the first socket, and the first socket and the second socket 321 can be correspondingly plugged and adapted to electrically connect the probe plate 310 and the ultrasonic front-end signal processing plate 320. The probe board 310 and the ultrasonic front-end signal processing board 320 are inserted in parallel through the insertion interface, so that the thickness of the first case 200 is further reduced, and the structural compactness of the whole machine is improved. The first interface and the second interface 321 may be PCI-E (Peripheral Component Interconnection-Express) slots, which are more compatible and faster to transmit.

The probe board 310 is provided with at least one probe interface 311 for plugging a probe, and the probe interface 311 may be disposed to face a side away from the second chassis 400. Generally, the number of the probe interfaces 311 of the desktop ultrasound device is three to five, and each probe interface 311 can be correspondingly plugged with an ultrasound probe. The signals collected by the ultrasonic probe are transmitted to the probe board 310, transmitted to the ultrasonic front-end signal processing board 320 through the probe board 310, processed by the ultrasonic front-end signal processing board 320 to generate secondary signals, transmitted to the back-end data calculation processing board 510, processed by the back-end data calculation processing board 510 to generate two-dimensional, three-dimensional or four-dimensional images, sound signals and the like of an image, and displayed by the display device 50. The probe interface 311 in this embodiment faces away from the second chassis 400, which may specifically be towards the front side, i.e. the side close to the medical operator. Alternatively, the probe interface 311 may be oriented toward the side of the patient where the patient is typically located, i.e., the right side in FIG. 2, to facilitate access of the ultrasound probe by the medical operator.

Referring to fig. 2 and 5, the rear data calculation processing board 510 of the rear module 500 is disposed perpendicular to the base 100, and the adaptor board 520 is vertically connected to the rear data calculation processing board 510. The adapter board 520 is mainly used for receiving the secondary signal transmitted from the shielded cable 600 and forwarding the secondary signal to the back-end data calculation processing board 510 for processing. The rear-end data calculation processing board 510 is provided with a third socket, the adapter board 520 is provided with a fourth socket corresponding to the third socket, and the third socket and the fourth socket can be correspondingly matched in a plugging manner. The third interface and the fourth interface can be PCI-E slots.

The back end module 500 further comprises a display card 530, the display card 530 is electrically connected to the back end data calculation processing board 510, the display card 530 is vertically connected to the back end data calculation processing board 510, and the display card 530 is arranged in parallel and at an interval with respect to the adapter board 520. The rear-end data calculation processing board 510 is provided with a fifth socket, the graphics card 530 is provided with a sixth socket corresponding to the fifth socket, the fifth socket and the sixth socket can be correspondingly matched with each other in a socket manner, and the fifth socket and the sixth socket can be PCI-E slots.

The back-end module 500 further includes a peripheral interface board (not shown) electrically connected to the back-end data calculation processing board 510, the peripheral interface board being vertically connected to the back-end data calculation processing board 510, and the peripheral interface board being arranged in parallel and at an interval with respect to the adapter board 520. The peripheral interface board may also be plugged into the back-end data computation processing board 510 in the form of a PCI-E slot. The peripheral interface board is provided with a plurality of interfaces for connecting external devices, for example: an interface of an external printer, an AVG interface or a USB interface, etc.

Wherein, on the basis that the probe interface 311 of the probe board 310 is designed to face the side where the medical care operator is located, the plurality of interfaces on the peripheral interface board can be designed to face the back side, i.e. the side away from the medical care operator. Alternatively, the probe interface 311 may be oriented toward the side of the patient generally, i.e., the right side in FIG. 2, while the various interfaces on the peripheral interface board may be designed to be oriented away from the side of the patient.

The above embodiments are merely exemplary structures, and the structures in the embodiments are not combined structures that are fixedly matched, and in the case of no structural conflict, the structures in multiple embodiments may be combined and used arbitrarily.

While the present invention has been described with reference to several exemplary embodiments, it is understood that the terminology used is intended to be in the nature of words of description and illustration, rather than of limitation. As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (13)

1. A desktop ultrasound device, comprising:

a base;

the host computer, set up on the base, the host computer includes: the front-end module and the rear-end module are integrally spaced from each other, the front-end module is packaged in a first case, the rear-end module is packaged in a second case, the second case is independent from the first case, the front-end module is provided with a first connector, the rear-end module comprises a rear-end data calculation processing board and a transfer board which are electrically connected with each other, and the transfer board is provided with a second connector; and

and one end of the shielding cable is connected with the first connector, the other end of the shielding cable is connected with the second connector, and the front-end module and the rear-end module are connected through the shielding cable to realize signal transmission.

2. The ultrasound apparatus of claim 1, wherein the first housing and the second housing are both disposed on the base in an upright position.

3. The desktop ultrasound device of claim 1, further comprising a power module disposed within the second chassis.

4. The desktop ultrasound device of claim 1, further comprising a power module disposed at a bottom of the base, the power module enclosed within a third enclosure, the power module spaced apart from the front end module and the back end module by the base.

5. The tabletop ultrasound device of claim 1, further comprising:

the lower end of the support column extends downwards into the host, the bottom end of the support column is fixed on the base, the support column extending into the host is arranged between the front end module and the rear end module at intervals, the upper end of the support column extends upwards out of the host, the first case and the second case are arranged at intervals, an interval space is formed between the first case and the second case, and the support column is arranged at the interval space; and

and the control panel is arranged at the part of the support column extending out of the host.

6. The ultrasound apparatus of claim 5, wherein the support post is a liftable support post, the support post comprising: the outer stand column and the inner stand column are arranged in the outer stand column, the inner stand column can ascend and descend relative to the outer stand column, and the control panel is arranged at the top end of the inner stand column.

7. The table type ultrasonic equipment according to any one of claims 1 to 6, wherein the front end module comprises a probe board and an ultrasonic front end signal processing board which are electrically connected with each other, a probe interface for plugging a probe is arranged on the probe board, the first connector is arranged on the ultrasonic front end signal processing board, the probe board and the ultrasonic front end signal processing board are both arranged perpendicular to the base, and the probe board is parallel to the ultrasonic front end signal processing board.

8. The desktop ultrasound equipment as claimed in claim 7, wherein a first socket is provided on the probe board, a second socket is provided on the ultrasound front-end signal processing board corresponding to the first socket, and the first socket and the second socket can be relatively plugged and adapted to electrically connect the probe board and the ultrasound front-end signal processing board.

9. The desktop ultrasound device of any one of claims 1 to 6, wherein the back end data computation processing board is arranged perpendicular to the base, and the adapter board is vertically connected to the back end data computation processing board.

10. The desktop ultrasound device according to claim 9, wherein a third socket is disposed on the back-end data calculation processing board, a fourth socket is disposed on the adapter board corresponding to the third socket, and the third socket and the fourth socket can be adapted to be plugged relatively.

11. The desktop ultrasound device according to claim 9, wherein the backend module further comprises a graphics card electrically connected to the backend data computation processing board, the graphics card is vertically connected to the backend data computation processing board, and the graphics card is arranged in parallel and spaced apart from the adapter board.

12. The desktop ultrasound equipment of claim 11, wherein a fifth interface is disposed on the back-end data computing board, a sixth interface is disposed on the graphics card corresponding to the fifth interface, and the fifth interface and the sixth interface can be adapted to each other in a relatively plugging manner.

13. The ultrasound equipment of claim 9, wherein the back-end module further comprises a peripheral interface board electrically connected to the back-end data computation processing board, the peripheral interface board having a plurality of interfaces for connecting to external devices, the peripheral interface board being vertically connected to the back-end data computation processing board, and the peripheral interface board being arranged in parallel and spaced apart from the adapter board.

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