CN220604870U - Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment - Google Patents

Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment Download PDF

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Publication number
CN220604870U
CN220604870U CN202322071979.9U CN202322071979U CN220604870U CN 220604870 U CN220604870 U CN 220604870U CN 202322071979 U CN202322071979 U CN 202322071979U CN 220604870 U CN220604870 U CN 220604870U
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power supply
portable
host
air inlet
ultrasonic
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CN202322071979.9U
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凌霄
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Sonoscape Medical Corp
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Sonoscape Medical Corp
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Abstract

The utility model relates to the technical field of medical equipment, and particularly discloses a mobile power supply, an ultrasonic trolley device, an ultrasonic device and an ultrasonic medical system of portable ultrasonic equipment, wherein the mobile power supply comprises a shell, an exhaust assembly and a battery module, the shell is limited with an exhaust cavity, an air inlet and an air outlet which are communicated with the exhaust cavity are formed in the outer wall of the shell, and the air inlet is used for being correspondingly arranged with a ventilation opening of a host; the exhaust component is arranged on the shell and is used for enabling heat exhausted by the host to enter the exhaust cavity from the air inlet and be exhausted from the air outlet; the battery module is arranged on the shell and is used for supplying power to the host. The portable power source reduces the limitation of the portable ultrasonic equipment on the technical problems of endurance, radiating effect and the like, and the portable ultrasonic equipment can develop in a light and thin direction better during manufacturing so as to meet the requirement of convenience.

Description

Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment
Technical Field
The embodiment of the application relates to the technical field of medical equipment, in particular to a mobile power supply of portable ultrasonic equipment, an ultrasonic trolley device, an ultrasonic device and an ultrasonic medical system.
Background
Medical ultrasonic equipment can be mainly divided into trolley type ultrasonic equipment and portable ultrasonic equipment (including notebook type ultrasonic equipment and plane type ultrasonic equipment), wherein the portable ultrasonic equipment has the advantages of smaller volume of a host computer and relatively comprehensive functions, and can support scene requirements of medical workers in outdoor treatment, transfer treatment among different hospitals and the like. At present, main ultrasonic brands in the international and domestic markets are successively introduced to have stronger performance and appearance which is more in line with the aesthetic portable ultrasonic equipment of the masses, and the portable ultrasonic equipment is increased in the markets of clinical departments, people and animals year by year.
In the related art, the portable ultrasonic equipment is different from the trolley type ultrasonic equipment, the portable ultrasonic equipment has smaller volume and cannot accommodate a large-volume large-capacity battery, so that the portable ultrasonic equipment has poor cruising ability under the condition of no mains supply and cannot meet the long-time use requirements of medical workers in the scenes of outdoors, emergency and the like; meanwhile, the high-performance portable ultrasonic equipment is higher in internal heat dissipation requirement, and the existing heat dissipation mode is generally realized by physical heat dissipation, so that a large enough flowing space is reserved in the portable ultrasonic equipment for flowing air flow, and a large enough installation space is reserved for installing a heat dissipation fan with a larger size.
For the above reasons, portable ultrasonic devices cannot be further developed in a thinner and lighter direction.
Disclosure of Invention
In view of the above, the present utility model aims to provide a portable power supply, an ultrasonic trolley device, an ultrasonic device and an ultrasonic medical system for a portable ultrasonic device, which can effectively reduce the problems of poor cruising ability and heat dissipation effect of the portable ultrasonic device, and the portable ultrasonic device can be better developed in a light and thin direction during manufacturing.
In order to achieve the above purpose, the present utility model provides the following technical solutions:
a mobile power supply for a portable ultrasound device, comprising:
the shell is defined with an exhaust cavity, and the outer wall of the shell is provided with an air inlet and an air outlet which are communicated with the exhaust cavity, wherein the air inlet is used for being arranged corresponding to a vent of the host;
the exhaust assembly is arranged on the shell and is used for enabling heat exhausted by the host to enter the exhaust cavity from the air inlet and be exhausted from the exhaust outlet;
the battery module is arranged on the shell and is used for supplying power for the host.
In some possible embodiments, the housing is provided with at least the air inlet for being located at the underside of the bottom of the host; and/or the shell is at least provided with an air inlet for facing the edge part of the host.
In some possible embodiments, the housing comprises at least a support portion for supporting at least a partial area of the bottom of the host.
In some possible embodiments, the support is for supporting a partial region of the bottom of the host; the side and/or top surface of the support part is provided with the air inlet positioned at the lower side of the bottom of the host.
In some possible embodiments, the support portion includes at least a first front plate portion and a first top plate portion connected to each other, the first top plate portion being configured to support a partial region of a bottom of the main unit, the first front plate portion being provided with the air inlet.
In some possible embodiments, the housing further includes a second front plate portion connected to the support portion, the second front plate portion being configured to be disposed opposite to the rear edge portion of the main unit, the second front plate portion being provided with the air inlet.
In some possible embodiments, the support part has a support surface for supporting a bottom of the main body, the support surface being disposed obliquely downward to be capable of obliquely supporting the main body.
In some possible embodiments, the support portion is provided with a guiding clamping groove, and the guiding clamping groove is used for enabling a foot pad or a protruding portion at the bottom of the host to slide and clamp in.
In some possible embodiments, the housing further defines a battery cavity and a first mounting port communicating the battery cavity with the exhaust cavity, and the outer wall of the housing is further provided with a second mounting port communicating the battery cavity; the mobile power supply further comprises a power supply control panel and a battery cover, wherein the power supply control panel is assembled at the first mounting port, and the battery cover is assembled at the second mounting port.
In some possible embodiments, the housing comprises an outer shell and a baffle, wherein: the shell is limited with a cavity, and the side wall of the shell is provided with the air inlet, the air outlet and the second mounting port; the air guide plate is arranged on the inner side of the shell so as to divide the cavity into the battery cavity and the exhaust cavity, and the air guide plate is used for guiding air flow entering from the air inlet to the air outlet.
In some possible embodiments, the exhaust assembly includes an exhaust fan disposed at least one of the intake port and the exhaust port.
In some possible embodiments, the exhaust fan further comprises a heat sink disposed on the exhaust fan and extending at least partially to the fan port of the exhaust fan, the heat sink for helping to transfer heat of the airflow to the fan port of the exhaust fan.
In some possible embodiments, the air inlet and the air outlet are disposed on opposite sides of the housing.
In some possible embodiments, the mobile power supply further includes an interface module disposed on the housing, where the interface module is at least provided with a data interaction interface, so that a storage medium connected to the mobile power supply can interact data with the host.
In some possible embodiments, the battery module of the mobile power supply has a specification configured to be identical to a battery module specification of the host.
In some possible embodiments, the mobile power supply further includes a display panel disposed on the housing, and the display panel is configured to display a power state of the mobile power supply.
In some possible embodiments, the mobile power supply further includes a charging module, where the charging module is disposed on the housing and is electrically connected to the battery module, and the charging module is used for charging connection with the host, so that the battery module supplies power to the host; the charging module is provided with one of an electric contact charging terminal, a wireless induction charging end and a magnetic attraction charging end.
From the above technical solutions, the embodiments of the present application have the following advantages: by applying the portable power supply of the portable ultrasonic equipment, the problems of poor cruising ability of the host, poor radiating effect and the like are solved, so that a large airflow space is not required to be reserved in the shell of the host for airflow to flow; and, there is no need to reserve a large installation space for installation of the larger-sized exhaust fan. Meanwhile, the inside of the shell of the host does not need to reserve a larger battery space for installing more battery modules. Therefore, the portable power source reduces the limitation of the portable ultrasonic equipment on the technical problems of endurance, radiating effect and the like, and the portable ultrasonic equipment can develop in a light and thin direction better during manufacturing so as to meet the requirement of convenience.
In order to achieve the above purpose, the utility model also provides an ultrasonic trolley device, which comprises a trolley and the mobile power supply, wherein the mobile power supply is detachably arranged on the trolley. Because the mobile power supply has the technical effects, the ultrasonic trolley device with the mobile power supply has the corresponding technical effects.
In some possible embodiments, the trolley comprises a base, a column and a supporting table, wherein the bottom of the column is fixedly connected with the base, the supporting table is connected with the top of the column, and the mobile power supply is detachably mounted on the supporting table.
In order to achieve the above purpose, the utility model also provides an ultrasonic device, which comprises the portable ultrasonic equipment and the mobile power supply, wherein the mobile power supply is used for supplying power and dissipating heat for the portable ultrasonic equipment. Because the mobile power supply has the technical effects, the ultrasonic device with the mobile power supply has the corresponding technical effects.
In order to achieve the above purpose, the utility model also provides an ultrasonic medical system, which comprises a trolley, the portable ultrasonic equipment and the mobile power supply, wherein the mobile power supply is detachably arranged on the trolley, and the trolley is used for bearing a host of the portable ultrasonic equipment. Because the mobile power supply has the technical effects, the ultrasonic device with the mobile power supply has the corresponding technical effects.
Drawings
The utility model is further described with reference to the accompanying drawings and examples, in which:
Fig. 1 is a schematic diagram of a front side structure of a mobile power supply according to an embodiment of the utility model;
FIG. 2 is a cross-sectional view of a mobile power supply according to an embodiment of the present utility model;
FIG. 3 is a schematic diagram of a rear structure of a portable power source according to an embodiment of the present utility model;
FIG. 4 is a schematic diagram of an explosion structure of a portable power source according to an embodiment of the present utility model;
fig. 5 is a schematic diagram of a separation state structure of a portable power source and a portable ultrasonic apparatus according to an embodiment of the present utility model;
fig. 6 is a schematic diagram of a charging state structure of a portable power source and a portable ultrasonic apparatus according to an embodiment of the present utility model;
fig. 7 is a schematic diagram of the overall structure of the trolley according to the embodiment of the present utility model.
Reference numerals:
the portable ultrasonic apparatus 10, the mobile power supply 20, the main body 11, the housing 100, the casing 110, the supporting portion 111, the first front plate portion 1111, the first top plate portion 1112, the supporting surface 1113, the guide card slot 1114, the first air inlet 1115, the second front plate portion 112, the second air inlet 1121, the second top plate portion 113, the rear plate portion 114, the air outlet 1141, the bottom plate portion 115, the second mounting port 1151, the end plate portion 116, the baffle 120, the cavity 130, the battery cavity 131, the exhaust cavity 132, the first mounting port 133, the battery cover 140, the exhaust assembly 200, the exhaust fan 210, the battery module 300, the display panel 400, the charging module 500, the electric contact charging terminal 510, the interface module 700, the data interaction interface 710, the power supply control panel 800; trolley 900, base 910, upright 920, and support table 930.
Detailed Description
Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.
In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.
In the description of the present utility model, the meaning of a number is one or more, the meaning of a number is two or more, and greater than, less than, exceeding, etc. are understood to exclude the present number, and the meaning of a number is understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.
In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.
In the description of the present utility model, the descriptions of the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
The portable power source 20 provided herein is used to power the portable ultrasound device 10, and the portable ultrasound device 10 includes, but is not limited to, a notebook ultrasound device, a tablet ultrasound device, and the like.
In addition, the mobile power supply 20 may be used to support the portable ultrasound device 10, where the portable ultrasound device 10 has the concepts of up, down, front, back, left, right, etc., in use, such as the orientation of the display of the portable ultrasound device 10 defaulting to the front. For convenience of description of the mobile power supply 20, the present application describes the structure of the mobile power supply 20 with reference to the up, down, front, rear, left, and right directions of the portable ultrasonic apparatus 10.
The present utility model provides a portable power supply 20 for a portable ultrasound device 10. The portable ultrasound device 10 may be a notebook ultrasound device, but is not limited to only this type of ultrasound device. The portable ultrasound device 10 includes a host computer 11, the host computer 11 integrating a control panel of the portable ultrasound device 10, and thus, the host computer 11 can be operated by a healthcare worker to control a part of functions of the portable ultrasound device 10. Referring to fig. 1 and 2, the portable power source 20 includes a housing 100, an exhaust assembly 200 and a battery module 300, wherein the housing 100 defines an exhaust cavity 132, an air inlet and an air outlet 1141 (refer to fig. 3) are provided on an outer wall of the housing 100, which are in communication with the exhaust cavity 132, and the air inlet is configured to correspond to a vent of the host 11; the exhaust assembly 200 is disposed in the housing 100, and is used for allowing heat exhausted by the host 11 to enter the exhaust chamber 132 from the air inlet and to be exhausted from the air outlet 1141; the battery module 300 is disposed in the housing 100 for supplying power to the host 11.
By applying the portable power source 20 provided by the application, the portable ultrasonic equipment 10 is connected with the host 11 in the use process, and the battery module 300 can be used for supplying power to the host 11 of the portable ultrasonic equipment 10, so that the portable power source 20 provides safe, stable and long-time power supply endurance for the portable ultrasonic equipment 10. Meanwhile, the exhaust assembly 200 may be activated during the power supply of the mobile power supply 20 to the main unit 11, and the exhaust assembly 200 provides the air inlet of the housing 100 with air suction capability. Because the air inlet of the housing 100 is disposed corresponding to the air vent of the host 11, the heat generated by the host 11 can enter the air exhaust cavity 132 along with the air flow in time under the action of the air exhaust assembly 200 and be exhausted from the air outlet 1141 of the housing 100, so that the mobile power supply 20 can help to accelerate the air flow in the host 11, so as to ensure the heat dissipation effect of the host 11.
In summary, by applying the portable power supply 20 of the portable ultrasonic device 10 provided by the application, the portable power supply 20 solves the problems of poor cruising ability and poor heat dissipation effect of the host 11, so that a large airflow space is not required to be reserved in the housing 100 of the host 11 for airflow to flow; and, there is no need to reserve a large installation space for installation of the larger-sized exhaust fan. Meanwhile, the housing 100 of the host 11 does not need to reserve a large battery space inside for installing more battery modules 300. From the above, the portable power source 20 of the present application reduces the limitation of the technical problems of the portable ultrasonic device 10 such as endurance and heat dissipation effect, and the portable ultrasonic device 10 can develop in a light and thin direction better during manufacturing to meet the requirement of convenience.
It can be appreciated that the portable power source 20 of the present application compensates or improves the problem of difficult heat dissipation of the portable ultrasonic device 10 currently on the market, and can help to accelerate the air flow inside the host 11 when the device works at full power, thereby improving the internal heat dissipation efficiency; the improvement of the heat dissipation efficiency means that the working pressure and time of the heat dissipation system in the host 11 can be reduced in a turning manner, the power loss of the part of the heat dissipation system is reduced, and the more stable working state, longer endurance and longer product life of the portable ultrasonic device 10 are realized.
It should be noted that, the air inlet of the housing 100 is configured to correspond to the air inlet of the host 11, which is understood to be disposed opposite to the air inlet of the host 11, so that, in the process of exhausting the air through the air inlet of the exhaust assembly 200, heat generated by the host 11 can timely enter the exhaust cavity 132 along with the air flow from the air inlet, and is exhausted through the air outlet 1141. Alternatively, it may be understood that the air inlet is disposed towards the external area corresponding to the air vent of the host 11, and the orientation angle of the air inlet may be set arbitrarily, so that, in the process of exhausting the air from the air inlet to the air exhaust assembly 200 through the air inlet, the heat generated by the host 11 can timely enter the air exhaust cavity 132 along with the air flow, and then be exhausted from the air outlet 1141. Or, an air guide channel is arranged between the air inlet and the air vent, and the air inlet and the air vent are correspondingly arranged, which are not listed one by one. Based on the above, the position of the air inlet and the position of the air vent of the host 11 are not limited to any positional relationship, and may be flexibly set according to the environmental requirements so as to be set corresponding to the air vent of the host 11.
In one possible embodiment, the bottom of the host 11 is typically provided with a vent, so that the host 11 can dissipate heat through the vent at its bottom; meanwhile, the rear edge portion of the main body 11 is generally provided with a vent, and the side edge portion of the main body 11 may be provided with a vent. In this application, the housing 100 is provided with at least an air inlet for being located at the lower side of the bottom of the main body 11, which may be defined as a first air inlet 1115 for convenience of description to distinguish other locations of air inlets. The first air inlet 1115 is located at a lower side of the bottom of the host 11, and thus, the first air inlet 1115 may be disposed corresponding to a vent of the bottom of the host 11. Because the heat of the host 11 is often concentrated at the bottom of the host 11 during the use process, the air flow at the bottom of the host 11 can be pumped away by the exhaust assembly 200 through the first air inlet 1115, so that the bottom of the host 11 is radiated, and the mobile power supply 20 can be used for radiating the bottom of the host 11, so that the radiating effect of the host 11 is improved.
The first air inlet 1115 may be disposed upward or horizontally toward the lower side of the bottom of the main unit 11, specifically according to the structure of the housing 100.
In another possible embodiment, the housing 100 is provided with at least an air inlet for facing the edge portion of the host 11, and for convenience of distinguishing the above-mentioned first air inlet 1115, the air inlet may be defined as a second air inlet 1121. The second air inlet 1121 is disposed toward the edge of the main unit 11, and thus, the second air inlet 1121 may be disposed opposite to the vent of the edge of the main unit 11. The second air inlet 1121 may be disposed opposite to the air vent of the rear edge of the host 11, or may be disposed opposite to the air vent of the side edge of the host 11 according to actual needs. In addition, since the heat generated by the host 11 is often discharged through the vent hole at the edge of the host 11 during the use process of the host 11, the exhaust assembly 200 improves the exhaust effect of the corresponding vent hole through the second air inlet 1121, so as to help accelerate the air flow inside the host 11 and ensure the heat dissipation effect of the host 11, thus the mobile power supply 20 can improve the heat dissipation effect of the host 11.
It should be noted that, the housing 100 may also be provided with the first air inlet 1115 and the second air inlet 1121 at the same time, where the exhaust assembly 200 may achieve a better heat dissipation effect at the bottom of the host 11 through the first air inlet 1115, and the exhaust assembly 200 may improve the heat dissipation effect of the host 11 through the second air inlet 1121, so that the mobile power supply 20 better solves the problem of poor heat dissipation effect of the host 11.
In some embodiments, the housing 100 may provide a cradle function as the portable ultrasound device 10. Specifically, the casing 100 includes a housing 110, and the housing 110 includes a supporting portion 111, where the supporting portion 111 is used to support the bottom of the host 11, so that the device is placed in a certain posture, thereby facilitating the medical staff to observe the display of the device conveniently. For example, referring to fig. 2, the supporting part 111 is used to support the bottom of the rear side of the main body 11, so that the portable ultrasonic device is obliquely placed, a medical staff can observe the display conveniently, and the mobile power supply 20 does not occupy the space of a precious operation table; the operation table is a platform for placing the host computer 11, and is, for example, a support table 930 of a middle carriage 900 described below (see fig. 7). Of course, the supporting portion 111 may also support the host 11 in other manners, and correspondingly, the structure of the supporting portion 111 is also adjusted accordingly.
In some embodiments, the housing 110 facilitates heat dissipation from the mobile power supply 20 to the host 11 through the arrangement of the supporting portion 111. Specifically, the supporting portion 111 is configured to support a partial region of the bottom of the main body 11, so that a region where heat is concentrated and a region of the vent are reserved in the bottom of the main body 11, and the reserved region is separated from the operation table. Because the first air inlet 1115 is disposed on the front side and/or the top surface of the supporting portion 111, the first air inlet 1115 can be located at the lower side of the bottom of the host 11, so that the air flow at the lower side of the host 11 can be smoothly pumped away by the air outlet assembly 200 through the first air inlet 1115, and better heat dissipation can be obtained at the bottom of the host 11.
It should be explained that the housing 100 supports the bottom of the host 11 through the supporting portion 111, in other words, the housing 100 is used for positioning the position and the posture of the host 11 through the supporting portion 111, so that the air inlet of the housing 100 is disposed corresponding to the air vent of the host 11, and thus, the air exhaust assembly 200 can preferably improve the heat dissipation effect of the host 11 through the first air inlet 1115.
In a further embodiment, referring to fig. 1 and 2, the supporting portion 111 includes at least a first front plate 1111 and a first top plate 1112, the first top plate 1112 is connected to an upper edge of the first front plate 1111, a bottom of a front side of the host 11 abuts against the console, and a bottom of a rear side of the host 11 abuts against the first top cover, so that the host 11 is obliquely placed on the supporting portion 111 of the housing 100. The first front plate 1111 is provided with first air inlets 1115 in a bar shape sequentially from the left end to the right end, and the first air inlets 1115 are disposed forward. Therefore, the supporting portion 111 adopts the above structure, and ensures that the supporting portion 111 can stably support the host 11, and ensures that the exhaust assembly 200 can preferably draw the air flow from the lower side of the host 11 through the first air inlet 1115, so as to perform better heat dissipation on the bottom of the host 11.
In one possible embodiment, referring to fig. 1 to 3, the case 110 further includes a second front plate portion 112, a second top plate portion 113, a rear plate portion 114, a bottom plate portion 115, and two end plate portions 116, wherein the first front plate portion 1111 is connected to a front edge of the bottom plate portion 115, one end plate portion 116 is connected to a left edge of the bottom plate portion 115, the rear plate portion 114 is connected to a rear edge of the bottom plate portion 115, the other end plate portion 116 is connected to a right edge of the bottom plate portion 115, and the first front plate portion 1111, the left end plate portion 116, the rear plate portion 114, and the right end plate portion 116 are sequentially and hermetically connected. The first top plate portion 1112 is connected between the two end plate portions 116 and the first front plate portion 1111, and is disposed facing upward. The second front plate portion 112 is connected between the two end plate portions 116 and the first top plate portion 1112, and is disposed facing forward. The second top plate 113 is connected between the two end plate portions 116, the second front plate portion 112, and the rear plate portion 114, and is disposed facing upward. Thus, the bottom plate portion 115, the first front plate portion 1111, the two end plate portions 116, the second front plate portion 112, the rear plate portion 114, the first top plate portion 1112, and the second top plate portion 113 define a cavity 130 therebetween. More specifically, referring to fig. 2, the whole housing 110 has a stepped structure, and the stepped portion of the housing 110 can be just used to support the bottom of the rear side of the host 11, so that the host 11 is obliquely placed on the operation table, which is convenient for the medical staff to observe the display screen of the host 11 and is also convenient for heat dissipation of the host 11. The exhaust port 1141 is provided in the rear plate 114.
Further, referring to fig. 2 and 4, the housing 100 further includes a baffle 120, the baffle 120 is fixedly connected to the bottom plate portion 115 and connected between the two end plate portions 116, the baffle 120 divides the cavity 130 into a battery cavity 131 and an exhaust cavity 132, and a first mounting opening 133 is further formed between an upper edge of the baffle 120 and an inner wall of the rear plate portion 114, and the battery cavity 131 is communicated with the exhaust cavity 132 through the first mounting opening 133. The bottom plate portion 115 is provided with a second mounting port 1151, the second mounting port 1151 communicates with the battery chamber 131, and the battery module 300 is mounted to and dismounted from the second mounting port 1151. The battery cavity 131 may be provided with one or more battery modules 300 according to actual needs.
Meanwhile, the portable power source 20 further includes a battery cover 140 and a power control panel 800, where the battery cover 140 is fixedly disposed at the second mounting opening 1151 by a screw or a clamping connection, and the power control panel 800 is fixedly assembled at the first mounting opening 133 and electrically connected to the battery module 300. Various functional devices, such as a functional device for detecting the power consumption of the battery module 300, etc., may be integrated on the power control panel 800 as needed.
It will be appreciated that, during the heat dissipation process of the host 11, referring to fig. 2, the air flow on the lower side of the host 11 enters the air exhaust cavity 132 through the first air inlet 1115 of the first front plate 1111, and the air flow entering the air exhaust cavity 132 may be guided by the baffle 120, and the air flow may flow smoothly from the position of the first air inlet 1115 to the position of the air outlet 1141 of the rear plate 114 and be discharged from the air outlet 1141.
In addition, the flow guide plate 120 limits the flow of the air flowing from the first air inlet 1115 into the exhaust cavity 132 to the battery module 300, so that the battery module 300 is effectively protected, and the service life of the battery module 300 is ensured.
In addition, the power control panel 800 is integrated with a control chip or other functional device that generates a large amount of heat when in use. This application installs power control panel 800 in first mounting mouth 133, and power control panel 800 has the function of sealed battery chamber 131, simultaneously, because the air current is changing always in exhaust chamber 132, the temperature of air current is lower for the temperature that power control panel 800 produced in the exhaust chamber 132, consequently, portable power source 20's cooling system not only is used for the heat dissipation of host computer 11, still is used for the heat dissipation of power control panel 800 to guarantee portable power source 20's life.
The housing 100 includes a bottom plate 115, a first front plate 1111, two end plates 116, a second front plate 112, a rear plate 114, a baffle 120, and the like, but is not limited to this configuration. The housing 100 may be adjusted to other structural forms according to practical needs to meet the installation requirement of the battery module 300 and the supporting and heat dissipation requirements of the host 11.
In some embodiments, the second front plate 112 is disposed opposite to the rear edge of the host 11, and a plurality of strip-shaped second air inlets 1121 are sequentially disposed at intervals from the left end to the right end of the second front plate 112, where the second air inlets 1121 are disposed opposite to the air vents of the rear edge of the host 11. Specifically, during use of the host 11, the air flow generated by the host 11 is often exhausted through the vent opening at the rear edge of the host 11, and the exhausted air flow enters the exhaust chamber 132 through the second air inlet 1121 and is exhausted through the air outlet 1141. The second air inlet 1121 is disposed opposite to the air vent at the rear edge of the host 11, so that the air exhaust assembly 200 can exhaust the air flow of the air vent of the host 11 through the second air inlet 1121, thereby facilitating the discharge of heat from the host 11, and further facilitating the improvement of the heat dissipation effect of the host 11 itself.
It can be understood that the housing 100 supports the bottom of the host 11 through the supporting portion 111, in other words, the housing 100 is used for positioning the position and the posture of the host 11 through the supporting portion 111, so that the second air inlet 1121 of the housing 100 is disposed corresponding to the air vent of the rear edge portion of the host 11, and thus, the air exhaust assembly 200 can preferably improve the heat dissipation effect of the host 11 through the second air inlet 1121.
In some embodiments, the upper side of the first top plate 1112 is a supporting surface 1113, and the supporting surface 1113 is used to support the bottom of the rear side of the host 11. Wherein the support surface 1113 is disposed obliquely downward from the rear edge to the front edge of the support surface 1113. Because the supporting surface 1113 is used for supporting the bottom of the back side of the main unit 11, the bottom of the back side of the main unit 11 is obliquely arranged on the supporting surface 1113, and the front edge of the main unit 11 is abutted against the operation desk, which is helpful for medical staff to observe the display of the portable ultrasonic device 10 and operate the operation panel of the main unit 11, such as the keyboard of the main unit 11. The host 11 can be stably placed on the console.
Further, referring to fig. 1, the mobile power supply 20 further includes a charging module 500, where the charging module 500 is disposed at the second front plate 112 or other positions of the housing 100. The charging module 500 has an electrical contact charging terminal 510 provided at the second front plate portion 112, the electrical contact charging terminal 510 being provided protruding forward. Meanwhile, a charging socket is provided at the rear edge of the host 11, and the supporting portion 111 is used for supporting the host 11, and the electric contact charging terminal 510 is just plugged into the charging socket of the host 11, so that the mobile power supply 20 supplies power to the host 11.
In some embodiments, the supporting surface 1113 of the first top plate 1112 is provided with at least two bar-shaped guide slots 1114, and one end of the guide slot 1114 extends through to the front edge of the first top plate 1112, and the other end extends backward. Referring to fig. 5 and 6, when the host 11 is assembled on the housing 100, the guide groove 1114 is used for sliding and clamping in a foot pad or a protruding portion at the bottom of the host 11, so that the first top plate 1112 can stably support the host 11, the host 11 is prevented from sliding easily on the first top plate 1112, the first air inlet 1115, the second air inlet 1121 and the ventilation opening of the host 11 are ensured to be correspondingly arranged, and the mobile power supply 20 can maintain a good heat dissipation effect on the host 11.
It will be appreciated that the foot pads or bosses on the bottom of the host 11 align with the charging sockets of the host 11 to electrically contact the charging terminals 510 during sliding movement along the guide card slots 1114, thereby facilitating assembly of the host 11 with the mobile power supply 20. And, the first top plate 1112 further locates the position of the host 11 through the guiding slot 1114, so that the first air inlet 1115 and the second air inlet 1121 are arranged corresponding to the ventilation opening of the host 11, and the mobile power supply 20 can have a better heat dissipation effect on the host 11.
The charging module 500 is not limited to the above-mentioned charging manner, and in some other embodiments, instead of providing the charging module 500 with the electrical contact charging terminal 510, the charging module 500 may be provided with a magnetic charging end, where the magnetic charging end is used for being magnetically connected with the device to supply power; alternatively, the charging module 500 may be provided with a wireless inductive charging terminal for wireless induction with the device to supply power.
In addition, the portable power source 20 can also adopt other modes such as wired harness connection charging, structural joint charging, and the like, and the charging mode is flexibly set according to actual needs. Of course, the portable power source 20 can also be provided with multiple charging modes at the same time, and according to the actual environment requirement, the medical staff adopts one of the charging modes to facilitate the charging of the host 11. Alternatively, when one of the charging modes is unavailable, the charging of the host 11 by the mobile power supply 20 may be completed by another charging mode.
In some embodiments, referring to fig. 1 to 3, the air inlet and the air outlet 1141 are disposed at opposite sides of the housing 100, and the air inlet is divided into a first air inlet 1115 and a second air inlet 1121. Specifically, the first air intake 1115 is provided to the first front plate portion 1111, the second air intake 1121 is provided to the second front plate portion 112, and the air exhaust 1141 is provided to the rear plate portion 114. Because the rear plate 114 is opposite to the first front plate 1111 and the second front plate 112, the air flow entering the exhaust chamber 132 from the first air inlet 1115 and the second air inlet 1121 can be smoothly discharged through the air outlet 1141, thereby avoiding the high temperature of the mobile power supply 20 caused by the air flow and ensuring the service life of the mobile power supply 20.
In some embodiments, the exhaust assembly 200 includes a plurality of exhaust fans 210, wherein a portion of the exhaust fans 210 may be disposed at the first air inlet 1115, so that the portion of the exhaust fans 210 may enable the first air inlet 1115 to have a sufficient air-extracting capability, so that heat at the bottom of the host 11 is quickly taken away, thereby ensuring a heat dissipation effect at the bottom of the host 11; meanwhile, another part of the exhaust fan 210 may be disposed at the exhaust port 1141, and the part of the exhaust fan 210 may enable the heat in the exhaust cavity 132 to be rapidly exhausted, so as to avoid the excessive temperature of the mobile power supply 20, and ensure the service life of the mobile power supply 20; in addition, the exhaust fan 210 has better air suction capability for the second air inlet 1121, so that the exhaust fan 210 makes the air flow in the host 11 enter the exhaust cavity 132 through the second air inlet 1121 quickly, and the heat dissipation effect of the host 11 is ensured.
It should be noted that the exhaust assembly 200 may be a micro pump, or other pumping device with pumping capability.
In addition, the exhaust fan 210 may be disposed outside the exhaust port 1141 or inside the exhaust chamber 132, and the exhaust fan 210 may be flexibly disposed according to actual needs, which is not particularly limited in this application.
Further, the exhaust assembly 200 further includes a heat conducting member (not shown), which may be a copper sheet or other metal member with better heat conducting capability. Each exhaust fan 210 is configured with a separate heat sink that extends at least partially to the fan port corresponding to the exhaust hand. When the air flows at a high speed, the heat conducting member can help to guide heat to the fan port, and the air flowing through the fan port absorbs the heat of the heat conducting member, so that the heat dissipation efficiency of the mobile power supply 20 to the host 11 is further improved.
In some embodiments, referring to fig. 4, the battery module 300 is detachably mounted to the housing 100, and the specification of the battery module 300 of the mobile power supply 20 is consistent with the specification of the battery module 300 of the portable ultrasonic device 10, so the battery module 300 of the mobile power supply 20 can be used as a backup battery of the portable ultrasonic device 10. It can be appreciated that when the outdoor electric quantity of the portable ultrasonic device 10 is insufficient, the medical staff can not only adopt the mobile power supply 20 to charge the portable ultrasonic device 10, but also directly detach the battery module 300 of the mobile power supply 20 to be used for replacing the battery module of the portable ultrasonic device 10, so that the portable ultrasonic device 10 is more flexible in use and more convenient in use.
In addition, the power supply of the portable ultrasonic device 10 and the portable power supply 20 adopt the battery module 300 with the same specification, so that an enterprise can uniformly purchase the battery module 300 and perform uniform management. In addition, the battery module 300 of uniform specification is also convenient to install and maintain in the following.
In some embodiments, referring to fig. 1, the portable power source 20 further includes a display panel 400, the display panel 400 is electrically connected to the power control panel 800, the power control panel 800 is configured to obtain the power state of the battery module 300 and transmit the power state to the display panel 400, and the display panel 400 is configured to display the power state of the battery module 300. Wherein, the display panel 400 is disposed on the second top plate 113, so that the medical staff can observe the display information of the display panel 400. Of course, the display panel 400 may be mounted at other positions of the housing 100, which is not limited in this application.
The power state includes, but is not limited to, a state of charge of the battery module 300, a charging indication, a time indication for full charge, a power health status indication, a low battery alarm indication, etc. The display panel 400 can help a user to intuitively observe various index states of the power supply, and avoid the problems that the power supply is not reasonably charged, is not fully charged when the user goes out and the like due to improper operation.
In addition, the display panel 400 may be an LED lamp, an LCD screen, an electronic ink screen, a dot matrix light strip, or the like.
In some embodiments, referring to fig. 3, the portable power source 20 further includes an interface module 700 disposed on the housing 100, and the interface module 700 is at least provided with an interface, and the type of the interface mainly includes: input type and output type. The input Type battery charging input interface comprises, but is not limited to, an internal battery charging input interface of the product, a USB interface, a Type-C interface and the like; the output type includes, but is not limited to, a host 11 charging interface, a network interface, a USB interface, a video transmission interface (HDMI), and the like. Wherein, part of the interfaces are data interaction interfaces 710, such as a network interface, a USB interface, a video transmission interface, etc., when the mobile power supply 20 is connected to the host 11, an external storage medium is connected to the data interaction interfaces 710 of the mobile power supply 20, so that the external storage medium can interact data with the host 11. The storage medium may be a usb disk, a mobile hard disk, a mobile phone, etc. From the above, the portable power source 20 of the present application adopts the above-mentioned interface module 700, so that the portable power source 20 is endowed with the function of the host 11 interface docking station, and the portable power source 20 increases the convenience of the host 11 in use.
In order to achieve the above objective, the present utility model further provides an ultrasonic trolley device, referring to fig. 1 and 7, comprising a trolley 900 and the above mobile power supply 20, wherein the mobile power supply 20 is detachably mounted on the trolley 900. Specifically, the above-mentioned portable power source 20 is adopted in the ultrasonic trolley device, and in the use process of the portable ultrasonic device 10, the portable power source 20 is connected with the portable ultrasonic device 10, and the battery module 300 can be used for supplying power to the portable ultrasonic device 10, so that the portable power source 20 provides safe and stable power supply and continuous voyage for the portable ultrasonic device 10 for a long time. Meanwhile, the power supply 20 may be activated during the power supply to the portable ultrasonic apparatus 10, and the air discharge assembly 200 may provide the air intake with air suction capability. Because the air inlet of the housing 100 is arranged corresponding to the air vent of the host 11, the heat generated by the host 11 can timely enter the air exhaust cavity 132 along with the air flow under the action of the air exhaust assembly 200 and be exhausted from the air outlet 1141 of the housing 100, so that the mobile power supply 20 can help to accelerate the air flow in the host 11, and the heat dissipation effect of the host 11 is ensured.
In addition, by the arrangement of the trolley 900, the trolley 900 is more convenient to carry the position of the mobile power supply 20 for use by medical staff.
In some possible embodiments, the trolley 900 includes a base 910, a stand 920, and a support stand 930, where the bottom of the stand 920 is fixedly connected to the base 910, the support stand 930 is connected to the top of the stand 920, and the mobile power source 20 is detachably mounted on the support stand 930. It can be appreciated that the trolley 900 adopts the above structure, the trolley 900 is simple in structure, and the supporting table 930 has a certain height, so that the placement and use of the host 11 and the mobile power supply 20 are facilitated. In addition, in other possible embodiments, the mobile power supply 20 may also be detachably mounted on the base 910 or the upright post 920, when the mobile power supply 20 is used on the trolley 900, the mobile power supply 20 may be detached from the base 910 or the upright post 920 to be placed on the supporting table 930, and then the portable ultrasonic device 10 is placed on the table surface of the supporting table 930 and the mobile power supply 20, so that charging and rapid heat dissipation are achieved by using the mobile power supply 20, and the portable ultrasonic device serves as a bracket function; of course, when the portable ultrasonic apparatus 10 needs to be used away from the cart 900, the portable power source 20 may be detached from the cart 900 and used away from the cart 900 together with the portable ultrasonic apparatus 10.
In addition, in other possible embodiments, the mobile power supply 20 may also be detachably mounted on the base 910 or the upright post 920, when the mobile power supply 20 is used on the trolley 900, the mobile power supply 20 may be detached from the base 910 or the upright post 920 to be placed on the supporting table 930, and then the portable ultrasonic device 10 is placed on the table surface of the supporting table 930 and the mobile power supply 20, so that charging and rapid heat dissipation are achieved by using the mobile power supply 20, and the portable ultrasonic device serves as a bracket function; of course, when the portable ultrasonic apparatus 10 needs to be used away from the cart 900, the portable power source 20 may be detached from the cart 900 to be used together with the portable ultrasonic apparatus 10.
Based on the mobile power supply provided in the above embodiment, the present utility model further provides an ultrasound apparatus, which includes any one of the mobile power supply 20 and the portable ultrasound device 10 in the above embodiment, where the mobile power supply 20 is used to supply power and dissipate heat to the portable ultrasound device 10. Specifically, the above-mentioned portable power source 20 is adopted in the ultrasonic device, and in the use process of the portable ultrasonic device 10, the portable power source 20 is connected with the portable ultrasonic device 10, and the battery module 300 can be used for supplying power to the portable ultrasonic device 10, so that the portable power source 20 provides safe, stable and long-time power supply and cruising for the portable ultrasonic device 10. Meanwhile, the power supply 20 may be activated during the power supply to the portable ultrasonic apparatus 10, and the air discharge assembly 200 may provide the air intake with air suction capability. Because the air inlet of the housing 100 is arranged corresponding to the air vent of the host 11, the heat generated by the host 11 can timely enter the air exhaust cavity 132 along with the air flow under the action of the air exhaust assembly 200 and be exhausted from the air outlet 1141 of the housing 100, so that the mobile power supply 20 can help to accelerate the air flow in the host 11, and the heat dissipation effect of the host 11 is ensured. As can be seen from the above, the portable power source 20 of the present application reduces the limitation of the portable ultrasonic device 10 in the technical problem, and the portable ultrasonic device 10 can be better developed towards the light and thin direction during manufacturing to meet the requirement of more convenience.
In order to achieve the above objective, the present utility model further provides an ultrasound medical system, referring to fig. 1 and 7, including a trolley 900, a portable ultrasound device 10 and the above mobile power supply 20, wherein the mobile power supply 20 is detachably mounted on the trolley 900, and the trolley 900 is used for carrying a host 11 of the portable ultrasound device 10. Specifically, the above-mentioned portable power source 20 is adopted in the ultrasonic device, and in the use process of the portable ultrasonic device 10, the portable power source 20 is connected with the portable ultrasonic device 10, and the battery module 300 can be used for supplying power to the portable ultrasonic device 10, so that the portable power source 20 provides safe, stable and long-time power supply and cruising for the portable ultrasonic device 10. Meanwhile, the power supply 20 may be activated during the power supply to the portable ultrasonic apparatus 10, and the air discharge assembly 200 may provide the air intake with air suction capability. Because the air inlet of the housing 100 is arranged corresponding to the air vent of the host 11, the heat generated by the host 11 can timely enter the air exhaust cavity 132 along with the air flow under the action of the air exhaust assembly 200 and be exhausted from the air outlet 1141 of the housing 100, so that the mobile power supply 20 can help to accelerate the air flow in the host 11, and the heat dissipation effect of the host 11 is ensured. In addition, by the arrangement of the trolley 900, the trolley 900 is more convenient to carry the position of the mobile power supply 20 for use by medical staff.
The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model. Furthermore, embodiments of the utility model and features of the embodiments may be combined with each other without conflict.

Claims (21)

1. A mobile power supply for a portable ultrasound device, the ultrasound device comprising a host, the mobile power supply comprising:
the shell is defined with an exhaust cavity, and the outer wall of the shell is provided with an air inlet and an air outlet which are communicated with the exhaust cavity, wherein the air inlet is used for being arranged corresponding to a vent of the host;
the exhaust assembly is arranged on the shell and is used for enabling heat exhausted by the host to enter the exhaust cavity from the air inlet and be exhausted from the exhaust outlet;
the battery module is arranged on the shell and is used for supplying power for the host.
2. A portable ultrasonic apparatus mobile power supply according to claim 1, wherein said housing is provided with at least said air inlet for being located at the underside of the bottom of said main body;
And/or the shell is at least provided with an air inlet for facing the edge part of the host.
3. The portable power supply of claim 1, wherein the housing includes at least a support portion for supporting at least a portion of a bottom portion of the main body.
4. A portable ultrasonic apparatus mobile power supply according to claim 3, wherein said support portion is for supporting a partial area of the bottom of said main body;
the side and/or top surface of the support part is provided with the air inlet positioned at the lower side of the bottom of the host.
5. The portable power supply of claim 4, wherein the support portion includes at least a first front plate portion and a first top plate portion connected to each other, the first top plate portion being configured to support a partial area of a bottom of the main unit, the first front plate portion being provided with the air inlet.
6. A portable ultrasonic apparatus mobile power supply according to claim 3, wherein the housing further comprises a second front plate portion connected to the support portion, the second front plate portion being arranged to be opposed to the rear edge portion of the main body, the second front plate portion being provided with the air inlet.
7. A portable ultrasonic apparatus according to any one of claims 3 to 6, wherein the support portion has a support surface for supporting a bottom portion of the main body, the support surface being disposed obliquely downward so as to be capable of obliquely supporting the main body.
8. A portable power supply for a portable ultrasonic apparatus according to any one of claims 3 to 6, wherein the support portion is provided with a guide clamping groove for sliding engagement of a foot pad or a boss portion of the bottom of the main body.
9. The portable power supply of a portable ultrasonic apparatus of claim 1, wherein the housing further defines a battery cavity and a first mounting port communicating the battery cavity with the exhaust cavity, the outer wall of the housing further being provided with a second mounting port communicating the battery cavity;
the mobile power supply further comprises a power supply control panel and a battery cover, wherein the power supply control panel is assembled at the first mounting port, and the battery cover is assembled at the second mounting port.
10. The portable power supply of a portable ultrasound device of claim 9, wherein the housing comprises a shell and a baffle, wherein:
The shell is limited with a cavity, and the side wall of the shell is provided with the air inlet, the air outlet and the second mounting port;
the air guide plate is arranged on the inner side of the shell so as to divide the cavity into the battery cavity and the exhaust cavity, and the air guide plate is used for guiding air flow entering from the air inlet to the air outlet.
11. The portable power supply of claim 1, wherein the exhaust assembly comprises an exhaust fan disposed at least one of the air inlet and the air outlet.
12. The portable power supply of claim 11, wherein the exhaust fan further comprises a heat sink disposed on the exhaust fan and extending at least partially to a fan port of the exhaust fan, the heat sink configured to assist in transferring heat from the airflow to the fan port of the exhaust fan.
13. The portable power supply of claim 1, wherein the air inlet and the air outlet are disposed on opposite sides of the housing.
14. The portable power supply of claim 1, further comprising an interface module disposed in the housing, the interface module being provided with at least a data interaction interface to enable a storage medium connected to the portable power supply to interact with the host.
15. The portable power supply of a portable ultrasonic apparatus according to claim 1, wherein the battery module of the portable power supply has a specification configured to be identical to a battery module specification of the host computer.
16. The portable power supply of claim 1, further comprising a display panel disposed on the housing, the display panel configured to display a power state of the portable power supply.
17. The portable power supply of a portable ultrasound device according to claim 1, further comprising a charging module, the charging module being disposed in the housing and electrically connected to the battery module, the charging module being configured to connect to the host so that the battery module supplies power to the host;
the charging module is at least provided with one of an electric contact charging terminal, a wireless induction charging end and a magnetic attraction charging end.
18. An ultrasound trolley device comprising a trolley and the mobile power supply of any one of claims 1 to 17, the mobile power supply being detachably mounted to the trolley.
19. The ultrasonic trolley assembly of claim 18 wherein the trolley comprises a base, a post, and a support platform, wherein the bottom of the post is fixedly connected to the base, the support platform is connected to the top of the post, and the power supply is removably mounted to the support platform.
20. An ultrasound apparatus comprising a portable ultrasound device and the mobile power supply of any one of claims 1-17 for powering and dissipating heat from the portable ultrasound device.
21. An ultrasonic medical system comprising a trolley, a portable ultrasonic device and the mobile power supply of any one of claims 1 to 17, wherein the mobile power supply is detachably mounted on the trolley and the trolley is used for carrying a host of the portable ultrasonic device.
CN202322071979.9U 2023-08-01 2023-08-01 Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment Active CN220604870U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202322071979.9U CN220604870U (en) 2023-08-01 2023-08-01 Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202322071979.9U CN220604870U (en) 2023-08-01 2023-08-01 Portable power source, ultrasonic trolley device, ultrasonic device and ultrasonic medical system of portable ultrasonic equipment

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CN220604870U true CN220604870U (en) 2024-03-15

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