KR20140068833A - sub-battery pack, battery pack having the sub-batterypack, portable ultrasonic scanning apparatus using thesub-battery pack and battery pack, and cart carryingthe sub-battery pack, battery pack and the portableultrasonic scanning apparatus - Google Patents

Abstract

A portable ultrasonic scanning apparatus according to one embodiment of the present invention includes a probe which generates an ultrasonic wave and receives the ultrasonic wave reflected from a testee; and an image processing part which processes ultrasonic data transmitted from the probe and generates image data; a display part which displays the image data; an embedded battery; a power source part which is located in the outside and supplies power to a batter pack which independently receives batteries, the embedded battery, or a probe which is connected to at least one among common power sources, the image processing part, and the display part; and a control part which controls the probe, the image processing part, or the display part, or the power source part to display the image data according to a predetermined work flow. The control part can control the power source part which allows the probe, the image processing part, and display part to receive power from one corresponding to the work flow among the battery pack, the embedded battery, or the common power sources.

Description

A sub-battery pack, a battery pack having the sub-battery pack, a portable ultrasonic diagnostic apparatus using the sub-battery pack, and a cart in which the sub- and cart carrying the sub-battery pack, the battery pack and the portableultrasonic scanning apparatus}

The present invention relates to a portable ultrasound diagnostic apparatus and a portable ultrasound diagnostic apparatus that are provided with a sub-battery pack and a battery pack for supplying power to the portable ultrasound diagnostic apparatus, portable ultrasound diagnostic apparatuses supplied with power from the sub- To the cart.

The ultrasonic diagnostic apparatus is an apparatus that generates ultrasonic waves and receives ultrasonic waves reflected from the examinee to determine the presence or absence of a disease or other abnormality of the examinee.

Such an ultrasonic diagnostic apparatus is mainly used in a clinic or a laboratory of a hospital, and its volume and weight are so large that it is not easy to move out of the hospital. Therefore, it was difficult to diagnose using ultrasound when it was difficult to visit the hospital because of the inconvenience of the testee.

In order to overcome such a restriction of movement, a portable ultrasonic diagnostic apparatus which is easy to carry has been introduced and is widely used in the medical industry today.

One aspect of the present invention is a portable ultrasonic diagnostic apparatus comprising: a sub-battery pack and a battery pack which are located outside and can supply electric power to a portable ultrasonic diagnostic apparatus; a portable ultrasonic diagnostic apparatus using a sub-battery pack or a battery pack; And the like.

A portable ultrasonic diagnostic apparatus according to an embodiment of the present invention includes a probe for generating an ultrasonic wave and receiving ultrasonic waves reflected from the examinee; An image processing unit for processing ultrasound data transmitted from the probe to generate image data; A display unit for displaying image data; Built-in battery; A power supply unit connected to at least one of a battery pack, an embedded battery, and a commercial power supply which is located outside and accommodates a plurality of batteries independently to supply power to the probe, the image processing unit, and the display unit; And a control unit for controlling the probe, the image processing unit or the display unit, or the power supply unit to display image data according to a predetermined workflow; And the control unit may control the power unit so that the probe, the image processing unit, and the display unit receive power from the battery pack, the built-in battery, or one of the commercial power supplies corresponding to the workflow.

In addition, when the power unit is connected to at least two of the battery pack, the built-in battery, and the commercial power supply, the control unit controls the portable ultrasound diagnostic apparatus to receive power from any one of the predetermined priority among the battery pack, The power supply can be controlled.

In addition, when the power source unit is connected to the battery pack and the built-in battery, the controller may control the power source unit so that the portable ultrasound diagnostic apparatus receives priority power from the battery pack.

The controller may control the power supply unit so that the portable ultrasonic diagnostic apparatus receives power from one of the plurality of batteries accommodated in the battery pack corresponding to the workflow, if the power supply unit is determined to receive power from the battery pack.

Further, the control unit may determine one battery corresponding to the workflow based on the usable time of each of the plurality of batteries.

The sub-battery pack or the battery pack according to an aspect of the present invention can be carried conveniently together with a portable ultrasonic diagnostic apparatus. In addition, it is convenient to connect the sub battery pack or the battery pack directly to the portable ultrasonic diagnostic apparatus or to replace the battery mounted in the battery pack with the built-in battery of the discharged portable ultrasonic diagnostic apparatus.

The portable ultrasonic diagnostic apparatus according to one aspect of the present invention is convenient because it can easily receive power from a sub-battery pack or a battery pack that can be carried together even if the built-in battery is discharged. In addition, power can be supplied from the sub battery pack or the battery pack, so that the portable ultrasonic diagnostic apparatus can be stably used for a long time without frequent charging.

The cart according to an embodiment of the present invention allows the battery pack and the portable ultrasonic diagnostic apparatus to be stably connected and can be conveniently moved.

1 is a view illustrating a battery pack and a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a battery pack having different widths of accommodating portions. FIG.
3 is a perspective view showing a battery pack having different lengths of receiving portions.
4 is a perspective view showing an assembled battery pack.
5 is a diagram illustrating a connection relationship between a control block and a battery pack of a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention.
FIG. 6 is a view showing a battery pack and a portable ultrasonic diagnostic apparatus connected to the battery pack, the receiving portions being electrically connected to each other with a structure different from that of FIG.
7 is a perspective view illustrating a cart according to an embodiment of the present invention.
8 is a view showing a mounting groove of the cart shown in Fig.
9 is a modification of the cart shown in Fig.
10 is a control flowchart illustrating an operation of connecting a battery according to charging / discharging of a battery in a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention.
FIG. 11 is a control flow chart in which charging of a battery is added in the battery connecting operation of FIG. 10; FIG.
12 is a control flowchart illustrating an operation of connecting a battery according to a workflow in a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 show a battery pack and a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention. 1, a battery pack 100 according to an embodiment of the present invention is connected to a power port 230 of a portable ultrasonic diagnostic apparatus 200 through a cable 320 to supply power to a portable ultrasound diagnostic apparatus do. The battery pack 100 includes a case 150 and a plurality of receiving portions 110 formed in the case.

The receiving portion 110 is partitioned from each other and the battery 120 for supplying electric power to the portable ultrasonic diagnostic apparatus 200 is accommodated in each receiving portion 110. The battery 120 may be manufactured to have the same size and function as the built-in battery 240 (FIG. 4) of the portable ultrasonic diagnostic apparatus 200. In this case, the battery 120 may be accommodated in the battery pack 100 Or may be directly attached to or detached from the portable ultrasound diagnostic device 200. [ In addition, each of the receiving portions 110 may be formed to have the same size so as to accommodate batteries of the same size (i.e., batteries having the same use time), or different sizes of the receiving portions 110 may be formed, Sized batteries (i.e., batteries having different usage times).

2, each of the receiving portions 110 may be configured to accommodate a battery having the same length L but different width W to have the same length L but various widths W, As shown in FIG. 3, a battery having the same width W but different length L may be accommodated to have the same width W but various lengths L. The width W and the length L of each accommodating portion 110 may be differently formed to accommodate batteries having different widths W and lengths L from the accommodating portions 110.

In the present embodiment, the barrier ribs are formed between the respective receiving portions. However, the barrier ribs may be partitioned only by a guide groove or the like for accommodating the battery without the barrier rib between the receiving portions.

The first terminal 130 is disposed on the inner rear surface of the receiving portion 110 and the first terminal 130 is in contact with the terminal 121 of the battery when the battery 120 is mounted. Although the first terminal 130 is provided on the inner rear surface of the receiving portion 110 in the present embodiment, the first terminal 130 is not limited to this position, It can be installed anywhere.

The first terminal 130 is electrically connected to the second terminal 140 disposed on the rear surface of the case 150. The position of the second terminal 140 is not limited to this position but may be provided anywhere on the outer wall surface of the case 150. In this case, .

The second terminal 140 is connected to the power port 230 of the portable ultrasonic diagnostic apparatus 200 through the cable 320 or when the battery pack 100 is mounted on the cart 400 to be described later, 3 terminal 440. [0052] In addition, the second terminal may be connected to a charging cable (not shown) used for charging the batteries.

Since the plurality of first terminals 130 connected to the second terminal 140 are independent from each other, even if the battery pack 100 and the portable ultrasound diagnostic apparatus 200 are electrically connected to each other, 100 are connected to only one of the plurality of batteries 120 accommodated in the battery.

That is, the plurality of pins (or holes) provided in the second terminal 140 are respectively connected to the first terminal 130 and are independent from each other, and connect the portable ultrasonic diagnostic apparatus 200 and the second terminal 140 Even if the cable 320 has a line corresponding to a plurality of pins (or holes) of the second terminal 140 so that the portable ultrasonic diagnostic apparatus 200 and the second terminal 140 are connected by the cable 320 Independent connection relationships between the first terminals are maintained.

In addition, the portable ultrasound diagnostic apparatus 200 includes a plurality of relays (220 in FIG. 4) for electrically connecting or disconnecting each battery 120 and the power source unit 210 (FIG. 4). In the portable ultrasound diagnostic apparatus 200, May be connected to only one battery 120 by driving the relays 220, and the connection with other batteries 120 may be blocked. A detailed description thereof will be described later.

The second terminal 120 is provided in the same number as that of the first terminal 130 and the first terminal 130 is connected to the first terminal 130. In this embodiment, And the second terminals may be connected to the terminals one by one.

Although the first terminal is described as being independent of each other even though the second terminal 140 is connected to the plurality of first terminals in the present embodiment, the second terminal 140 may include all of the first terminals 140, And may be connected in series with the battery pack 130 so that all the batteries stored in the battery pack 100 may be used as one battery.

In addition, the battery pack according to an embodiment of the present invention may be formed as an assembled type (or mutually removable type) as shown in FIG. That is, the battery pack can be divided into a plurality of sub-battery packs 160, and one sub-battery pack 160 has one storage unit 110. In addition, each sub-battery pack is provided with a first terminal and a second terminal separately, and at least one coupling portion 161, 162) is formed.

The engaging portions 161 and 162 are protrusions 161 or grooves 162. The protrusions 161 formed in one sub battery pack are slid into the grooves 162 formed in another sub battery pack so that the two sub battery packs are coupled to each other .

The sub-battery packs 160 located at both ends of the battery pack 100 when coupled to one of the sub-battery packs 160 are formed with coupling portions 161 or 162 on only one outer side, The battery pack located between the packs has engaging portions 161 and 162 formed on both outer sides thereof.

4, a groove 162 is formed in the vicinity of the longitudinal edge of the outer right side of the sub-battery pack located at the left end of the battery pack 100 when the battery pack 100 is coupled with one battery pack, The projections 161 are formed near the longitudinal edges of the outer left side surface of the sub-battery pack.

A protrusion 161 is formed near the left side vertical edge of the sub-battery pack positioned at the center when the battery pack is coupled with one battery pack, and a groove 162 is formed near the right side vertical edge, The groove portion 162 of the battery pack and the protrusion portion 161 of the right-side sub-battery pack.

In FIG. 4, the slide coupling between the protrusion 161 and the groove 162 is illustrated to form the assembled battery pack, but the sub battery packs may be coupled in different ways.

4, protrusions 161 and grooves 162 may be formed on both side surfaces of all the sub-battery packs, so that the sub-battery packs can be used without having to distinguish each sub-battery pack.

As described above, the battery pack 100 according to one embodiment of the present invention supplies electric power to the portable ultrasound diagnostic apparatus with at least one battery, so that the portable ultrasound diagnostic apparatus can be stored for a long time .

5 and 6 illustrate a battery pack and a portable ultrasonic diagnostic apparatus connected thereto according to an embodiment of the present invention. 5, a portable ultrasound diagnostic apparatus 200 according to an embodiment of the present invention includes a probe 260, a beam former 270, an image processing unit 290, a display unit 280, a relay 220, A power supply port 230, a power supply unit 210, a memory 241, and a control unit 250.

Probe 260 includes a 1D or 2D or 3D converter. The probe 260 transmits the ultrasonic beam (or signal) generated by suitably delaying the transmission pulse signals in each transducer to the examinee along the transmission scan line. Then, the ultrasonic signals (i.e., the ultrasonic echo signals) reflected from the examinee are input to the respective transducers at different reception times and converted into the electrical reception signals.

The beam former 270 converts a received signal of an analog form into a digital signal when a received signal is transmitted from the prub 260. Then, the digital signal is received and focused to generate a reception focusing signal.

The image processing unit 290 includes a signal processor 291, a scan converter 292, an image processor 293, and a video processor 294. The signal processor 291 performs an envelope detection process for detecting the intensity of the receive focusing signal based on the receive focus signal focused by the beam former 270 to form ultrasound image data.

The scan converter 292 scans and converts the ultrasound image data output from the signal processor.

The image processor 293 performs various image processing (for example, B mode image processing and Doppler image processing) on the scan-converted ultrasound image data.

The video processor 294 processes the ultrasound image data transmitted in the image process.

The display unit 280 displays the ultrasound image data output from the video processor 294 as an ultrasound image.

The relay 220 is connected between the power supply port 230 and the power supply unit 210 to connect or disconnect each battery 120 and the power supply unit 210 accommodated in the battery pack 100, ) Is performed in accordance with the control command of the control unit 250. [ The relay 220 is not used in the portable ultrasonic diagnostic apparatus 200 receiving power from the first terminals 130 connected in parallel to the power supply unit 210 and the second terminal 140 connected in series.

In the present embodiment, the relays 220 are used to connect or disconnect the respective batteries 120 and the power source unit 210. However, instead of the relays 220, Devices (such as MOSFET switches) may also be used.

The power supply port 230 is connected to the second terminal 140 of the battery pack 100 and the fourth terminal 450 of the cart 400 to be described later by a cable 320, (210).

The power supply unit 210 may be connected to a commercial power supply via the power adapter 310 or may be connected to the built-in battery 240 to supply power to the prus unit 260 or the like. The power supply unit 210 may be connected to the external battery pack 100 via the power supply port 230 to supply power to the prus part 260 or the like. Here, the technology for supplying electric power to the commercial power source or the embedded battery 240 and supplying power to the probe 260 is well known in the art, and thus a detailed description thereof will be omitted.

The power supply unit 210 is connected to the second terminal 140 via the relay 220, the power supply port 230, and the cable 320. Here, even if the relay 220, the power supply port 230, the cable 320, and the second terminal 140 are all connected, the batteries installed in the battery pack are independent of each other. Therefore, by controlling the ON or OFF operation of the relay 220, only the power source unit 210 and one battery 120 can be connected. Control of the relay 220 on or off will be described later.

Although the power supply unit 210 is described as being connected to one battery 120 in the present embodiment, the power supply unit 210 may be connected to all the batteries 120 at the same time. That is, the second terminal 140 of the battery pack 100 is connected in series with all the first terminals connected in parallel to each other. When the power supply unit 210 is connected to the second terminal 140, 210 may be connected to all the batteries 120 at one time. In this case, it is not necessary that the relay 220 is disposed between the power source unit 210 and the power source port 230. The portable ultrasonic diagnostic apparatus 200 is configured to connect all the batteries 120 accommodated in the battery pack 100 to one battery Can be used like.

The power supply unit 210 is connected to the commercial power supply via the power adapter 310 when the built-in battery 240 or the battery 120 accommodated in the battery pack 100 needs to be charged (for example, when the charged amount is less than 5% If it is, it supplies the charging power to the battery requiring charging. Here, the determination of the charged amount of the built-in battery 240, the charging method, and the like are well-known techniques, and a detailed description thereof will be omitted (refer to Korean Patent Laid-Open Publication No. 2000-25198). The control unit 250 performs the driving of the relay 220 when the battery pack 100 is charged, which will be described later.

When two or more of the battery pack 100, the built-in battery 240, and the commercial power supply are connected to each other at the same time, the power supply unit 210 is configured to be selected as a power supply source, May select one of them as a power supply source by a control command of the power supply source. For example, if the battery pack 100 and the built-in battery 120 are simultaneously connected to the power supply unit 210, the power supply unit 210 may be configured to preferentially use the power of the battery pack 100.

The memory 241 stores a list of batteries to be connected to the power unit 210 when executing each application or a work flow. A detailed description thereof will be described later.

The control unit 250 controls the overall operation of the portable ultrasonic diagnostic apparatus 200. The controller 250 monitors the charged amount of the battery pack 100 and the built-in battery 240 to charge the battery pack 100 and the built-in battery 240, if necessary. Here, the operations related to the built-in battery 240 are well known in the art, so a detailed description thereof will be omitted.

The control unit 250 senses the voltage of the first terminals 130 of the battery pack 100 by sensing the voltage across the relays 220, 120 are mounted. If there are a plurality of batteries 120 stored in the battery pack 100, the relay 220 connected between the battery 120 and the power supply unit 210 is turned on and the remaining relays 220 are turned off. Accordingly, the power supply unit 210 can be connected to one of the plurality of batteries 120 accommodated in the battery pack 100.

The control unit 250 determines the amount of charge of the battery 120 while receiving power from one battery 120 and displays the charged amount on the display unit 280. [ The determination of the charged amount of the battery and the display method thereof are well known in the art, so a detailed description thereof will be omitted.

The control unit 250 displays a warning on the display unit 280 when the charged amount of the battery 120 is equal to or lower than a reference value (for example, when the charged amount is 5% or less). The control unit 250 turns on the relay 220 connecting the other battery 120 and the power source unit 210 when the charged amount of the battery is below the reference value, The relay 220 is turned off.

As described above, when the discharge of one battery approaches, the controller 250 connects the other battery and the power source unit 210, and disconnects the battery and the power source unit 210 from each other. At this time, the connection order of each battery 120 and the power supply unit (i.e., each first terminal and the power supply unit) 210 is determined in advance, and the controller 250 drives the relay 220 in order, The battery 120 is connected to the power supply unit 210. [

The control unit 250 connects the other battery and the power source unit 210 when the discharge of the battery 120 that supplies power to the power source unit 210 is close to the power source unit 210. The control unit 250 maintains the connection between the existing battery and the power source unit 210, As shown in FIG.

In addition, when the battery 120 is replaced, the control unit 250 displays the fact on the display unit 280.

Although the power supply unit 210 is described as being connected to one battery 120 in the present embodiment, the power supply unit 210 may be connected to all the batteries 120 at once as shown in FIG. 6. In this case, The control unit 250 determines the charge amount of the entire battery, and the display unit 280 displays the charge amount of the entire battery.

The portable ultrasound diagnostic apparatus 200 may be connected to or disconnected from the battery based on the charging or discharging of the battery. the portable ultrasound diagnostic apparatus 200 may be connected to other batteries according to the work flow.

To this end, the memory 241 of the portable ultrasonic diagnostic apparatus 200 stores a list of batteries to be used in execution of each application or workflow, and a priority is assigned to each application or workflow, When the flow is executed, the battery is selected based on the application or workflow having the highest priority among the flows. .

For example, if three batteries are installed in a battery pack and the available time for each battery is 10 minutes (battery A), 20 minutes (battery B), and 30 minutes (battery C) When performing a workflow that takes a long time like an ultrasonic wave, it is necessary to connect the battery C having the longest battery usage time, and when the work flow requiring a short time such as a thyroid ultrasonic wave to check the state of the thyroid is performed, The shortest battery A may be connected. To this end, the memory 241 stores a workflow-battery list such as a precise ultrasound-battery C and a thyroid ultrasound-battery A.

As described above, the portable ultrasonic diagnostic apparatus 200 according to the present exemplary embodiment receives power from the battery pack 100 in which at least one battery 120 can be mounted, so that the user frequently charges the built-in battery 240 So that it can be used for a long time.

7 and 8 show a cart according to an embodiment of the present invention. 7 and 8, a cart 400 according to an embodiment of the present invention includes a support 410 on which the portable ultrasonic diagnostic apparatus 200 is placed, a plurality of And includes a wheel 420.

A mounting groove 430 for mounting a battery pack 100 accommodating a plurality of batteries 120 is provided on a front surface of the support table 410. In this embodiment, the mounting groove 430 is formed on the front surface of the cart. However, the mounting groove 430 is not limited to this position but may be installed at another position of the support 410. A gripping groove 460 is provided at the entrance of the mounting groove 430 to allow the user to easily grasp the battery pack 100 when the battery pack 100 is attached or detached.

A third terminal 440 is provided on the rear surface of the mounting groove 430 to contact the second terminal 140 of the battery pack 100 when the battery pack 100 is mounted. Although the third terminal 440 is formed on the rear surface of the mounting groove 430 in this embodiment, the mounting groove 430 is not limited to this position, 140, it may be installed at another position of the mounting groove 430.

The third terminal 440 is connected to a fourth terminal 450 provided outside the support 410. The fourth terminal 450 is connected to the power port 230 of the portable ultrasonic diagnostic apparatus 200 through a cable 320. The relay 220 is installed between the third terminal 440 and the fourth terminal 450 and the relay 220 is provided between the third terminal 440 and the fourth terminal 450. In the portable ultrasound diagnostic apparatus 200, And may be driven by a control command of the control unit 250 of the control unit 200.

On the other hand, the cart 400 may be formed as shown in FIG. 9, a holder 470 for holding the portable ultrasonic diagnostic apparatus 200 and a support 410 for supporting the holder 470 are separately provided and hinged to each other.

On the upper surface of the support table 410, a receiving portion 110 for receiving each battery is provided. A first terminal (not shown) is provided on the inner bottom surface of the receiving portion 110, and the first terminal is in contact with the terminal 121 of the battery when the battery 120 is mounted. The first terminal is connected to the fourth terminal 450.

The front surface of the holder 470 is provided with an LED display portion 480 for indicating the state of charge of each battery mounted in the receiving portion. The LED display unit 480 is divided into three areas, and the LEDs of the respective areas indicate whether the batteries installed in the three storage units 110 are charged or discharged. For example, if the battery in the left receptacle is charged and the batteries in the center and right receptacles are discharged, the left area LED of the LED display part 480 is green and the center and right LEDs of the LED display part 480 are green It can be displayed in red.

The LED display unit 480 operates according to a control command of the control unit 250, and other details such as determination of the amount of charge of each battery are the same as those of the carts of FIGS. 7 and 8.

As described above, the cart 400 according to an embodiment of the present invention can easily provide a battery pack 100 having at least one battery 120 and a portable ultrasonic diagnostic apparatus 200 receiving power from the battery pack 100 And the use time of the portable ultrasonic diagnostic apparatus 200 is made longer.

Hereinafter, a connection operation of the portable ultrasonic diagnostic apparatus 200 and the battery according to the charged amount of the battery will be described with reference to FIGS. 10 and 11. FIG.

The control unit 250 monitors the voltage of the first terminals 130 by sensing the voltage across the relay 220 and determines whether the battery 120 is mounted on the battery pack 100. Then, it is determined whether there are a plurality of batteries 120 located in the battery pack 100 (510). If there is one battery 120 located in the battery pack 100, the relay is turned on 530. If a plurality of batteries 120 are located in the battery pack 100, one battery 120 and the power source 210 (520), and turns off the remaining relays (220).

The controller 250 checks the charged amount of the battery 120 connected to the power supply unit 210 and determines whether the charged amount of the battery 120 is less than a reference value (540, 550). If the charge amount of the battery 120 is lower than the reference value, the controller 250 turns on the relay 220 connecting the other battery 120 and the power source 210, 210 are turned off (560). At this time, the display unit 280 displays the charged amount of the battery 120, and alerts the user when the discharge of the battery 120 is near. Also, the display unit 280 informs the user of the replacement of the battery 120.

The battery 120 is disconnected from the relay 220 connecting the battery 120 and the power supply unit 210 when the discharge of the existing battery 120 is close to the upper part of the battery 120. Alternatively, Is connected to the commercial power supply through the power adapter 310 and turns on the relay 220 between the other battery 120 and the power supply unit 210 and turns on the relay 220 connecting the existing battery 120 and the power supply unit 210 220 may also be charged (660) while maintaining the on state.

At this time, the controller 250 determines whether the charging is completed by checking the charged amount of the existing battery 120. When the charging is completed, the controller 250 turns off the relay 220 connecting the existing battery 120 and the power source 210 ).

Since the remaining operations 600 to 650 of FIG. 11 are the same as those of FIG. 10, description thereof will be omitted.

Hereinafter, a battery connection operation according to a workflow of a portable ultrasonic diagnostic apparatus according to an embodiment of the present invention will be described with reference to FIG. When the user selects a workflow to be executed (700), the control unit 250 confirms (710) a battery to be used in execution of the workflow in the memory 241. Then, the relay 220 connecting the battery and the power source unit 210 is turned on and the remaining relays 220 are turned off (720). Therefore, a battery suitable for each workflow can be connected to the portable ultrasonic diagnostic apparatus 200.

100: Battery pack 110:
130: first terminal 140 second terminal
200: Portable ultrasonic diagnostic apparatus 210: Power supply unit
220: Relay 250:
400: Cart 430;

Claims (5)

A probe for generating an ultrasonic wave and receiving ultrasonic waves reflected from the examinee;
An image processing unit for processing ultrasound data transmitted from the probe to generate image data;
A display unit for displaying the image data;
Built-in battery;
A power supply unit connected to at least one of a battery pack, a built-in battery, and a commercial power supply for supplying power to the probe, the image processor, and the display unit; And
A control unit for controlling the probe, the image processing unit, the display unit, or the power supply unit to display image data according to a predetermined workflow; Lt; / RTI >
Wherein the controller controls the power supply unit such that the probe, the image processing unit, and the display unit receive power from one of the battery pack, the embedded battery, and the commercial power supply corresponding to the workflow. The method according to claim 1,
The portable ultrasonic diagnostic apparatus according to claim 1, wherein when the power source unit is connected to at least two of the battery pack, the built-in battery, and the commercial power supply, the portable ultrasonic diagnostic apparatus determines whether the battery pack, And controls the power supply unit to receive power from any one of the power supply units. 3. The method of claim 2,
Wherein the controller controls the power supply unit such that the portable ultrasonic diagnostic apparatus preferentially receives power from the battery pack when the power supply unit is connected to the battery pack and the built-in battery. The method according to claim 1,
Wherein the control unit controls the power supply unit so that the portable ultrasonic diagnostic apparatus receives power from one of the plurality of batteries accommodated in the battery pack corresponding to the workflow when the power supply unit is determined to receive power from the battery pack Portable ultrasound diagnostic device. 5. The method of claim 4,
Wherein the controller determines one battery corresponding to the workflow based on a usable time of each of the plurality of batteries.

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