JP2020054491A - Medical electronic instrument - Google Patents

Abstract

To easily measure an electrocardiogram by the desired number of channels according to a subject.SOLUTION: There is provided a medical electronic instrument for measuring an electrocardiogram by using an electrode for an electrocardiogram. The medical electronic instrument includes an instrument body for measuring an electrocardiogram by the predetermined number of channels, and a connector provided to an electrode for an electrocardiogram, which is detachably attached to the instrument body for connecting the electrode for an electrocardiogram to the instrument body. The connector includes a channel indication part for indicating the number of channels to the instrument body when attached to the instrument body.SELECTED DRAWING: Figure 13

Description

  The present invention relates to a medical electronic device, and more particularly, to a portable medical electronic device.

  2. Description of the Related Art Conventionally, as a medical electronic device that acquires biological information not only at rest but also during exercise and daily life, specifically, an electrocardiogram, for example, a Holter electrocardiograph as disclosed in Patent Document 1 is known. I have.

  The Holta monitor carries an electrocardiograph main body to which electrodes attached to the body surface are connected, and acquires long-term continuous biological information in daily life via the electrodes. In some Holter monitors, the number of ECG channels to be recorded can be selected in accordance with the accuracy of the ECG to be acquired.

In general, as the number of channels increases, a more accurate ECG can be obtained. However, increasing the number of channels means that the load on the subject increases due to the increase in the number of electrodes attached to the subject's body. In total, it means that the recording time is shortened.
A medical worker such as a doctor connects a lead connector derived from an electrode portion corresponding to a desired number of channels to an apparatus main body which selects and sets a desired number of channels according to a symptom of a subject or the like. Then, the electrocardiogram of the subject is measured.

JP-A-2013-135774

  By the way, in the Holter monitor, the selection and setting of the number of channels by a medical worker are generally performed manually on the device body side. For example, a medical worker sets a recording mode in which an electrocardiogram is measured and recorded by performing a button operation while viewing a menu screen displayed on a liquid crystal display unit provided in the Holter monitor. When the recording mode is selected by the medical staff, the Holter monitor records an electrocardiogram of the number of channels according to the selected recording mode.

  However, in the Holter monitor which is further downsized to improve portability, the display unit and the operation unit are further simplified, so that the medical staff can use the simplified display unit and the operation unit. It tends to be difficult to manually select and set the number of channels. In addition, since a setting operation such as performing a plurality of settings with a small number of buttons is troublesome, it is desired that a Holter electrocardiograph simply sets a corresponding channel according to an electrode to be connected.

  The present invention has been made in view of the above points, and provides a Holter monitor that can be easily measured with a desired number of ECG channels according to a subject.

The medical electronic device of the present invention,
A medical electronic device that measures an electrocardiogram using an electrocardiogram electrode,
A device main body for measuring an electrocardiogram with a predetermined number of channels,
A connector that is provided on the electrocardiogram electrode, is detachably attached to the device main body, and connects the electrocardiogram electrode to the device main body,
Has,
The connector employs a configuration having a channel indicator for instructing the number of channels to the device main body when attached to the device main body.

  According to the present invention, measurement can be easily performed with a desired number of ECG channels according to a subject.

1 is an external perspective view of a medical electronic device according to an embodiment of the present invention. FIG. 2 is a plan view of the medical electronic device according to the embodiment of the present invention. 1 is a front view of a medical electronic device according to an embodiment of the present invention. FIG. 2 is a rear view of the medical electronic device according to the embodiment of the present invention. FIG. 2 is a left side view of the medical electronic device according to the embodiment of the present invention. FIG. 2 is a right side view of the medical electronic device according to the embodiment of the present invention. FIG. 4 is a plan view of the medical electronic device according to the embodiment of the present invention, in which an engagement state between a housing and a connector is released. FIG. 8 is a sectional view taken along line AA of FIG. 7. It is a figure showing the connector removed from the case in the medical electronic equipment concerning an embodiment of the invention. It is a side view of the connector in which the battery was mounted. It is a perspective view of the electrode for single use electrocardiogram provided with a connector. It is a top view of the electrode for single use electrocardiogram provided with a connector. FIG. 2 is a perspective view illustrating a main configuration of the connector. It is an external appearance perspective view which shows the apparatus main body protected by attaching the cover member. It is a top view which shows the apparatus main body protected by attaching the cover member. It is a left view which shows the apparatus main body protected by attaching the cover member. It is a right view which shows the apparatus main body protected by attaching the cover member. It is a front view of a cover member. It is a rear view of a cover member. FIG. 20A and FIG. 20B are diagrams in which the engagement state between the housing and the connector is released using the cover member in the medical electronic device. 21A to 21D are views showing the operation of pulling out the engaging claw from the notch.

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

  The medical electronic device to which the present invention can be applied is, for example, a device that uses a battery as a driving source and measures biological information using a living body mounting part mounted on a subject. In the present embodiment, the medical electronic device is a device having a housing to which an electrocardiogram electrode as a living body mounting portion is connected via a connector. The living body mounting unit may be any unit that is mounted on the subject and acquires biological information of the subject, and may be a pulse oximeter or the like. Further, the medical electronic device is preferably a portable electronic device. In the present embodiment, as an example, a description will be given as an example adapted to a Holter monitor, but the present invention is not limited to this. The medical electronic device according to the present invention may have any configuration as long as it has a connector connected to the living body mounting portion and a device main body having a function of being driven by a battery when the connector is attached.

  1 to 6 are an external perspective view, a plan view, a front view, a rear view, a left side view, and a right side view of a medical electronic device according to an embodiment of the present invention. FIG. 7 is a plan view of the medical electronic device according to the embodiment of the present invention, in which an engagement state between the housing and the connector is released. FIG. 8 is a cross-sectional view taken along line AA of FIG. FIG. 9 is a diagram showing the connector detached from the housing in the medical electronic device according to the embodiment of the present invention, and FIG. 10 is a side view of the connector on which a battery is mounted.

  The medical electronic device 1 as the Holter monitor according to the present embodiment is used by attaching the connector 20 from which the electrode 30 is led out to the device main body 10 from which the cover member 80 (see FIG. 14) has been removed. The connector 20 of the present embodiment is a connector with an electrode integrated with the electrode 30, and is configured as a single use electrocardiogram electrode to be discarded after use, a so-called disposable electrode (see FIGS. 11 and 12). .

  The battery serving as the drive source of the medical electronic device 1 is, for example, a button-type battery. In particular, among the button batteries, a coin-shaped flat-disk battery having a negative electrode-side convex shape may be used. The medical electronic device 1 of the present embodiment is driven by a coin-type lithium battery.

  Specifically, the medical electronic device 1 can supply power to the device main body 10 from the battery B (see FIGS. 7 to 9) by attaching the connector 20 in which the battery B is disposed to the device main body 10. The apparatus main body 10 is configured to be driven. In this embodiment, the battery B is a single-use primary battery that is discarded together with the electrode 30 after use. However, the present invention is not limited to this. You may use it.

  The medical electronic device 1 illustrated in FIGS. 1 to 9 includes a device main body 10, a connector 20 detachably attached to the device main body 10, and a lock mechanism 50.

<Equipment main body 10>
In the present embodiment, the device main body 10 connects the connector 20 and measures an electrocardiogram as biological information of the subject via the electrode 30 as a living body mounting portion.
As shown in FIGS. 1 and 7 to 9, the device main body 10 has a housing 12 formed in a hollow rectangular flat plate shape. The housing 12 has an insertion opening 132 (see FIG. 8) that is open on one end surface 12 a side and that is continuous with the housing 11 inside the housing 12. Note that, in the present embodiment, the device main body 10 is configured to be compact so that the subject can carry it.

  The connector 20 is attached to the device main body 10 in a state where the battery housing portion 24 of the connector 20 is inserted into the insertion opening 132. In the present embodiment, the insertion opening 132 is opened at the distal end of the rectangular connector mounting portion 13 protruding from the one end surface 12a of the device main body 10. The insertion opening 132 is covered and closed by covering the connector mounting portion 13 with the connector main body 22 of the connector 20. Thereby, the device main body 10 forms a rectangular plate-like body (see FIGS. 1 and 2).

  When the connector 20 is attached, the device main body 10 can be supplied with power from the battery B disposed on the connector 20, and is supplied with power and driven.

  As shown in FIG. 8, the device main body 10 includes a housing section 11 that houses the battery housing section 24 together with the battery B, and a circuit section 17 that is connected to the battery B and the electrode 30 via the connector 20. The housing 11 houses the battery housing 24 inserted through the insertion opening 132. The circuit unit 17 is a circuit for performing an operation of acquiring an electrocardiogram. The circuit section 17 is arranged in the housing section 11. The circuit section 17 includes a plus terminal connection section 172 connected to the plus terminal (pole Ba) of the battery B when the connector 20 is inserted, and a minus terminal connection section connected to the minus terminal (pole Bb) of the battery B. 174 and an electrode connection portion (terminal portion) 176 (see FIG. 7) connected to a terminal portion (base portion) 32 on the base end side of the electrode 30.

  In the circuit portion 17, the plus terminal connection portion 172 and the minus terminal connection portion 174 are arranged so as to extend toward the insertion opening 132 side in the accommodation portion 11 of the device main body 10, and are inserted together with the battery accommodation portion 24. Connectable to battery B. The electrode connection portion 176 is arranged in the housing portion 11 adjacent to the housing area for housing the battery housing portion 24, and is provided so as to protrude from a portion of the connector mounting portion 13 adjacent to the insertion opening 132.

  Specifically, the positive terminal connection portion 172 is disposed inside the housing portion 11 so as to extend to the distal end side of the connector mounting portion 13 along the back surface of the front surface of the housing 12. In the accommodating portion 11 in the housing 12, the contact of the minus terminal connection portion 174 is arranged so as to face the contact of the plus terminal connection portion 172 in the thickness direction of the housing 12.

  Thereby, when the connector 20 is attached to the device main body 10, the battery accommodating portion 24 inserted into the accommodating portion 11 through the insertion opening 132 is located between the plus terminal connection portion 172 and the minus terminal connection portion 174. And the battery B held by the battery accommodating portion 24 comes into contact with the positive terminal connecting portion 172 and the negative terminal connecting portion 174 so as to be sandwiched therebetween. At the same time, that is, when the connector 20 is mounted on the device main body 10, the electrode connection portion 176 on the device main body 10 side is covered with the connector 20 at a position adjacent to the area where the battery housing portion 24 is housed. Are electrically connected to the terminal portions 32 of the electrodes 30.

Further, when the connector 20 is attached to the device main body 10, the circuit unit 17 measures an electrocardiogram with the number of channels specified by the channel specifying unit 61.
When the connector 20 is attached to the device main body 10 and the battery accommodating unit 24 is inserted through the insertion slot 132, the circuit unit 17 determines the number of channels of the electrode 30 to be measured by the desired channel using the biological information ( It has a function of switching to a circuit for acquiring an electrocardiogram.
Specifically, the circuit unit 17 includes a two-channel measurement circuit and a three-channel measurement circuit that perform measurement using the electrode 30 to be connected, and a switch that switches between them. The switch is pressed by the existing channel indicator 61 and measures on two channels. When the channel indicator 61 is not present, the number of channels is different from the number of channels when the switch is pressed. It is configured to perform the measurement.

  The circuit unit 17 includes a display unit 14, an event key 15 as an operation unit for operating the medical electronic device 1, an enter key 16, and the like. The display unit 14 is disposed such that the display surface is exposed to the outside on the surface of the housing 12, and mechanical switches such as an event key 15 and an enter key 16 are respectively provided on the side wall surface and the front end wall surface of the housing 12. It is arranged so that it can be pressed freely. The display unit 14 displays the measured value during the actual measurement. In the present embodiment, the display unit 14 displays the measured value of the biological information that is started at the same time when the connector 20 is attached. The event key 15 marks biological information (electrocardiogram) being measured. For example, the event key 15 is pressed when the subject under measurement feels uncomfortable, and marking is performed on the electrocardiogram when uncomfortable. Note that the event key 15 may change the display mode or setting content displayed on the display unit 14. The enter key 16 displays or stores biometric information by confirming the display mode or setting content selected by the event key 15.

  The lock mechanism 50 holds the attached state between the device main body 10 and the connector 20. The lock mechanism 50 has an engaging portion 52 provided on the connector 20 and an engaged portion 54 detachably engaged with the engaging portion 52.

  The engaged portion 54 engages with the engaging portion 52 of the connector 20 to connect the connector 20 to the device main body 10, that is, to connect the circuit portion 17 of the device main body 10 to the battery B and the electrode 30. State is maintained. Thus, the medical electronic device 1 can be driven as an electrocardiograph. In the present embodiment, the device main body 10 is connected to the power supply from the battery B by engaging the device main body 10 with the connector 20 to maintain the attached state of the connector 20 to the device main body 10, Is a power source for the circuit unit 17 on the device body 10 side, and the circuit unit 17 measures the electrocardiogram of the subject via the electrode 30.

  In the present embodiment, the engaging portion 52 and the engaged portion 54 are engaged by inserting one of the two into the other.

The engaged portion 54 includes a concave notch 541 provided on each of two opposing side walls of the opening peripheral portion surrounding the connector mounting portion 13 having the insertion port 132, and a window 542 in the notch 541. Having. In the present embodiment, the engaged portion 54 is provided on each of the short side walls of the rectangular opening peripheral portion surrounding the connector mounting portion 13.
The engaged portion 54 is engaged with the engaging portion 52 (the engaging claw portion 522) of the connector 20 by being inserted and disengaged. Specifically, the notch 541 of the engaged portion 54 engages with the engaging portion 52 of the connector 20 inside the notch 541 when the connector is mounted on the connector mounting portion 13 of the device body 10. The claw portion 522 engages with the claw portion 522 exposed to the outside.

  The cutout portion 541 is formed on the outer surface of the housing 12 so as to extend so as to intersect with the opening direction of the insertion slot 132, that is, the mounting direction of the connector 20. The notch 541 allows an arm 86 that is a part of the cover member 80 (see FIGS. 14 to 20) to be inserted when the connector 10 is mounted.

  In the present embodiment, the cutout portion 541 is formed in a concave shape that opens laterally and upward (on the front surface side) at the end on the one end surface 12a side on both side walls of the device main body 10. The notch 541 connects the inside and outside of the housing 12 via the window 542. Note that the cutout portion 541 may be formed in a concave shape that is opened in the lateral and vertical directions (the front surface side and the rear surface side). The direction in which the cutout portion 541 extends on both side walls of the device body 10 may be any direction. In the present embodiment, the direction extends in the direction orthogonal to the mounting direction of the connector 20.

The window 542 is provided inside the concave cutout 541 and communicates the inside of the cutout 541 with the inside of the insertion slot 132.
The window 542 has an engaging claw 522 serving as the engaging portion 52 of the connector 20 inserted therein, and the inserted engaging claw 522 is elastically deformed in a direction intersecting with the insertion direction so that the window 542 (specifically) Is engaged with the frame 543) on the opening side of the window 542. This restricts movement of the device main body 10 and the connector 20 away from each other, that is, movement of the connector 20 with respect to the device main body 10 in the withdrawing direction (the direction of the arrow in FIG. 5).

  The windows 542 are provided on both side walls on the side of the one end face 12 a having the insertion opening 132 in the housing 12, so that the engaging claw 522 that engages with the windows 542 has the notch 541. It is exposed to the outside of both sides of the device body 10 through the main body. That is, the engaging claw 522 of the connector 20 extends from the center side in a direction orthogonal to the insertion direction and engages with the window 542 via the window 542, and the connector 20 engages with the device main body 10. Thus, the attachment state between the connector 20 and the device main body 10 is securely held.

<Connector 20>
In the present embodiment, the connector 20 is provided at the base end of the electrode 30 and houses the battery B. The connector 20 connects the electrode 30 to the device main body 10 (specifically, the circuit section 17 in the device main body 10) by being attached to the device main body 10, and connects the device main body 10 from the battery B to the medical electronic device. The power is supplied to the electrocardiograph 1 and electrically connected so as to be drivable. In the present embodiment, the connector 20 is attached to the device main body 10 in a watertight manner.

  The connector 20 includes a connector main body 22, a guide section 23, a battery accommodating section 24, a short circuit prevention section 26, a terminal section 32 of the electrode 30, an engaging section 52, a channel indicating section 61, and a waterproof member 70.

  In the present embodiment, the connector main body 22 is a rectangular case-shaped body that opens in the mounting direction, and the battery housing portion 24 and the terminal portion 32 are spaced apart from the peripheral wall in the rectangular case-shaped body in the opening direction. It is provided so as to protrude. The opening edge 222 of the connector main body 22, the battery accommodating portion 24, and the terminal portion 32 function as a fitting portion fitted on the one end surface 12a side of the device main body 10.

  When the connector 20 is attached to the device main body 10, the connector main body 22 is provided with engaging portions 52 on both side walls that are flush with both side walls of the device main body 10. Further, the connector body 22 is provided with a plate-like guide portion 23 protruding from the bottom surface side of the opening edge portion 222.

  The engagement portion 52 is provided so as to protrude from the opening edge portion 222 in the direction of attachment to the device main body 10, and has an engagement claw portion 522 at a distal end portion.

  In the present embodiment, the engagement portion 52 is formed as a protruding piece that is inserted into the device main body 10 along the inside of both side walls of the housing 12 of the device main body 10. The engagement claws 522 are provided to protrude to both sides in each of the engagement portions 52.

  In the present embodiment, the engaging claw 522 is elastically deformed and inserted into the device main body 10, that is, into the housing 12, and engages with the window 542 from inside the housing 12. . The engagement claw 522 and the window 542 with which the engagement claw 522 engages may be any engagement claw as long as the engagement claw 522 and the window 542 engage with each other to maintain the attached state between the device body 10 and the connector 20. The portion 522 may be provided on the device body 10 side, and the window portion 542 may be provided on the connector 20 side.

The guide portion 23 functions as a guide when attaching the connector main body 22 to the device main body 10. Specifically, the guide portion 23 is arranged along the outside of the bottom surface of the device main body 10. The guide portion 23 slides on the bottom surface of the device main body 10 when attaching the connector 20 to the device main body 10, and guides the connector 20 to the device main body 10 so that the connector 20 can be smoothly mounted on the device main body 10.
The guide portion 23 guides the engagement between the engaged portion 54 and the engaging portion 52 due to the relative movement of the device main body 10 and the connector 20 in the mounting direction.

The waterproof member 70 is provided on the opening edge 222 so as to surround the opening of the connector 20.
When the connector 20 is attached to the device body 10, the waterproof member 70 is deformed by being sandwiched between the opening edge of the device body 10 (the opening edge of the one end surface 12 a) and the opening edge 222 of the connector 20. Are joined in a watertight manner.

  The waterproof member 70 is formed of an annular elastic body. The waterproof member 70 is made of an elastic material such as a flexible resin.

  In the present embodiment, the waterproof member 70 is provided over the entire surface of the opening edge 222 of the connector body 22 in the connector 20.

Specifically, as shown in FIGS. 9 and 13, the waterproofing member 70 includes a rectangular frame-shaped portion 72 surrounding the connector mounting portion 13 having the insertion port 132, and two sides from the corner of the frame-shaped portion 72. And a projecting piece 74 projecting from
The frame-shaped portion 72 is arranged on the opening edge portion 222 so as to surround the opening of the connector main body 22, and when the connector 20 is attached to the device main body 10, the battery housing is provided around the connector mounting portion 13, that is, inside the connector mounting portion 13. The periphery of the insertion opening 132 into which the part 24 is inserted and the connection part between the electrode connection part 176 and the terminal part 32 are waterproofed.

  The frame-shaped portion 72 is formed with a step so that the inner peripheral portion 722 projects more than the outer peripheral portion 724. When the connector 20 is attached to the device main body 10, the inner peripheral portion 722 is pressed by both sides and deforms so as to escape to a step portion with the outer peripheral portion 724, so that the device main body 10 and the connector 20 are more watertight. In this way, the waterproofness is improved.

  The protruding piece portion 74 is arranged on the opening edge portion 222 so as to sandwich the engaging portion 52 in the thickness direction (vertical direction), and when the connector 20 is attached to the device main body 10, the thickness direction (vertical direction). ) (The direction in which the connector 20 is inserted) in the direction perpendicular to the direction of insertion (the insertion direction of the connector 20). Thereby, the housing 12 and the connector main body 22 can be made to adhere to each other more water-tight over the entire surface of the portion that is in contact with each other at a position orthogonal to the insertion direction.

  Thus, the inside of the medical electronic device 1 surrounded by the opening edge 222 is closed in a watertight manner, and is in a completely sealed state.

The battery housing portion 24 is connected to the device main body 10 so that when the connector 20 is attached to the device main body 10, the battery B can supply power to the device main body 10.
In the present embodiment, the battery accommodating portion 24 holds the battery B in a state where the polarities of the battery B are arranged on the surface along the mounting direction of the connector.
In the present embodiment, as shown in FIGS. 8 to 10 and FIG. 13, the battery accommodating portion 24 extends from the back surface of the connector main body 22 (in the present embodiment, the surface from which the electrode 30 is led out). It has a recessed tray portion 242 protruding in the mounting direction and depressed on the upper side. The tray unit 242 places the battery B above the tray unit 242, in this embodiment, on the front surface side of the device body 10. The tray section 242 is provided with a short circuit prevention section 26.

  When the battery accommodating portion 24 is inserted into the accommodating portion 11 in the device main body 10 through the insertion opening 132 of the device main body 10, the respective poles Ba and Bb of the battery B to be accommodated are connected to the corresponding device main body 10 side. (Positive terminal connection part 172 and negative terminal connection part 174).

In the present embodiment, when the battery B is correctly placed, that is, when the battery B is accommodated in the battery B is formed so that it can be smoothly inserted into the insertion port 132 in the mounting direction together with B. In the present embodiment, the state in which the protruding pole Bb of the battery B is placed on the tray portion 242 so as to face the bottom side is configured so that the battery B is substantially parallel to the mounting direction. The tray portion 242 is formed in a concave shape recessed on the bottom surface side so that the convex pole Bb of the battery B is fitted.
Further, in the present embodiment, a step 27 is provided at the base end side edge of the tray portion 242 so as to be higher than the center side. The battery B on the tray 242 is inserted into the tray 242 from the distal end of the tray 242 (the part that becomes the distal end when inserted into the insertion slot 132) toward the proximal end, and the base of the battery B is inserted. The edge on the end side is placed on the step 27 and engaged with the step 27 so that the edge is smoothly placed on the tray portion 242.

  When the battery B is placed on the tray portion 242 with the convex pole Bb of the battery B facing the bottom surface side of the tray portion 242, the edge of the battery is inserted into the step 27. Engage. When the battery B is to be placed with the battery Ba facing the bottom of the tray portion 242 with the pole Ba opposite to the pole Bb facing the edge of the battery B, the step 27 The battery B cannot be smoothly accommodated in the battery accommodating section 24, that is, the battery B cannot be smoothly accommodated in the battery accommodating section 24. As described above, in the tray portion 242, the concave portion formed corresponding to the battery shape and the step 27 function as a reverse insertion preventing portion of the battery B that enables the battery B to be accommodated in a correct direction (posture). I do.

  With this configuration, even when the battery B is placed on the tray unit 242 with the poles Ba and Bb reversed, the edge of the pole Ba engages with the step 27 if the pole Ba faces the bottom side. Therefore, the battery B is placed on the tray 242 in an inclined state. As described above, the battery B can be prevented from being reversely inserted into the battery accommodating portion 24 by checking the posture of the battery B. Further, when the battery B is inclined in the battery accommodating portion 24, it is difficult to insert the battery B into the insertion slot 132, and it is possible to prevent the battery B from being reversely inserted into the battery accommodating portion 24.

  A pole notch 246 is formed at the tip end of the tray portion 242, that is, at the central portion on the free end side. The pole notch 246 exposes one pole of the battery B on the tray 242, in this embodiment, a negative pole Bb below the tray 242.

  The battery housing portion 24 is arranged between the plus terminal connection portion 172 and the minus terminal connection portion 174 when housed inside the device main body 10, and the minus terminal connection portion 174 is arranged inside the pole cutout portion 246. Is done.

When the connector 20 containing the battery B is attached to the device main body 10, the short-circuit preventing portion 26 correctly connects the pole Ba (Bb) of the battery B to the terminal connection portion 172 (174) of the device main body 10, Avoid short circuit. In the present embodiment, the short-circuit preventing portion 26 prevents the pole Ba of the battery B from being connected to the negative terminal connecting portion 174 not corresponding to the pole Ba when the battery housing portion 24 is inserted into the insertion slot 132. Is provided.

  The short-circuit preventing portion 26 is arranged so as to partition the pole cutout portion 246 at a widthwise central portion of the edge portion on the distal end side of the tray portion 242 at the edge portion on the distal end side of the tray portion 242. Further, the short-circuit preventing portion 26 is formed in a rib shape protruding toward the front surface side (upper side, in the present embodiment, the positive pole side) of the battery B to be housed. The short-circuit prevention unit 26 is arranged so as to cover a pole on the front surface side of the battery B (the outer peripheral surface which becomes a positive pole together with the surface of the battery B) housed in the battery housing unit 24 from the front end side.

  Thereby, the short-circuit prevention unit 26 becomes an obstacle when the negative terminal connection unit 174 in the device main body 10 contacts the pole Ba of the battery B when the battery housing unit 24 is inserted into the insertion slot 132. . Accordingly, the short-circuit prevention unit 26 is configured such that the terminal (for example, the negative terminal connection unit 174) of the device body 10 that contacts the pole on the back side of the battery B (for example, the pole Bb) contacts the pole Ba on the front side of the battery B. To prevent

  Further, the connector 20 has a connector attachment confirmation unit 29 for identifying that the connector 20 is attached to the device body 10 when the connector 20 is fitted and attached to the device body 10.

  In the present embodiment, the connector attachment confirmation portion 29 is a projection that projects in the insertion direction at a portion of the connector 20 on the side attached to the device main body 10, for example, at the tip of the battery housing portion 24. When the protrusion comes into contact with a mounting switch (not shown) provided on the substrate side corresponding to the protrusion, a signal indicating the mounting of the connector 20 to the device main body 10 is output in the circuit unit 17 and the mounting of the electrode 30 is completed. Is confirmed.

The terminal portion 32 of the electrode 30 is electrically connected to the electrode connection portion 176 when the connector 20 is attached to the device main body 10, and connects the electrode 30 to the device main body 10.
In the connector main body 22, the terminal portion 32 is in the frontage direction which is the longitudinal direction of the insertion slot 132, that is, in the width direction of the housing 12 with respect to the battery accommodating portion 24, and is horizontally adjacent in the present embodiment. Is provided.

  In the present embodiment, the terminal portion 32 is disposed in the rectangular block-shaped connection block 28 provided adjacent to the battery housing portion 24 in the lateral direction, and is exposed on the opening side of the opening edge portion 222. . In the present embodiment, the connection block 28 is provided in the connector main body 22 so as to protrude so as to have the same length as the length of the peripheral wall portion from the back surface to the opening edge 222. The terminal portion 32 is disposed in a plurality of holes provided on the protruding end surface of the connection block 28, is an electrode connection portion 176 on the connector 20 side, and has a pin-like terminal urged to be able to advance and retreat in the axial direction. By doing so, it is possible to electrically connect to the pin-shaped terminals. The terminal portion 32 and the electrode connection portion 176 may have any configuration as long as the terminal portion 32 and the electrode connection portion 176 are electrically connected to each other when the connector 20 is attached to the device main body 10. The terminal portion 32 may be a pin-shaped terminal that can be freely retracted, and the electrode connection portion 176 may be a terminal that contacts the pin-shaped terminal in a state where the pin-shaped terminal is pressed backward.

  The channel instructing unit 61 illustrated in FIGS. 9 and 13 instructs the device main body 10 on the number of electrocardiogram channels acquired by the medical electronic device 1 when the connector 20 is attached to the device main body 10.

  In the present embodiment, the channel indicator 61 is a rod-like body projecting into the insertion slot 132 and is configured to be removable. The number of designated channels can be changed depending on the presence or absence of the rod-shaped body. In the present embodiment, when the battery accommodating section 24 is inserted through the insertion slot 132, the circuit section 17 on the device body 10 is pressed by the channel indicating section 61, and the channel of the electrode 30 to be measured is There is a switch (not shown) for switching to a circuit for acquiring biological information (electrocardiogram) with two channels. When the switch is not pressed by the channel instruction unit 61, the biological information is configured to perform measurement on a different number of channels from that when the switch is pressed, and in this embodiment, to perform measurement of biological information on three channels. ing.

  That is, the circuit unit 17 uses the electrodes 30 to measure biological information (electrocardiogram) in three channels by eliminating the channel instruction unit 61 on the connector 20 side. On the other hand, if the connector 20 has the channel indicator 61, the switch of the substrate is pressed by the channel indicator 61, and the substrate measures the biological information (mainly an electrocardiograph) in two channels using the electrode 30. To change. In the present embodiment, the channel indicator 61 is formed of a rod-shaped body. However, when the connector 20 is attached to the device main body 10, when the connector 20 is attached to the device main body 10, Any configuration may be used as long as the number of channels to be measured is specified and measurement can be performed with the specified number of channels.

  The electrode 30 provided with the connector 20 in the present embodiment is an electrode with a connector integrated with the connector 20 as shown in FIGS. 11 and 12, and as described above, can be discarded after use together with the connector 20. It is a disposable electrode.

  The electrode 30 is fixed together with the connector 20 to a mounting surface portion 30a having an adhesive portion and a liner via a separator at a branch portion 33 on the terminal portion 32 (see FIG. 11) side. The guide leads 36 are branched from the branch portions 33, and the tip of each guide lead 36 is connected to an electrode 34. The electrode portion 34 is provided on the mounting surface portion 30b having an adhesive portion and a liner with a separator interposed therebetween. The electrode portion 34 is attached to a desired body surface portion of the subject corresponding to each channel in each channel. The unit 34 is mounted on the subject.

  In the present embodiment, the mounting position of the electrode unit 34 of the electrode 30 is changed, and the channel indicating unit 61 indicates the channel to be measured to the device main body 10 in response to the change. The number of channels changes.

As described above, according to the present embodiment, even when the number of channels to be measured is different via electrodes 30 connected to device main body 10, connector 20 has channel indicator 61, so connector 20 is connected to device main body 10. The number of channels to be measured by the channel indicator 61 can be easily changed only by attaching to 10.
If the electrode 30 provided with the connector 20 can change the channel to be measured only by changing the mounting position of the electrode unit 34 without changing the electrode 30 itself, the connector 20 may be connected to the device body. By simply attaching the device 10, the number of channels to be measured can be instructed to the device main body 10 by the channel indicator 61, and measurement can be performed at a desired number of ECG channels according to the subject.

<Cover member 80 of medical electronic device 1>
14 to 19 are views showing the device main body 10 in the medical electronic device 1 in which the connector 20 has been removed and the cover member 80 has been attached and protected. 14 to 17 are an external perspective view, a plan view, a front view, a left side view, and a right side view showing the device main body 10 protected by attaching the cover member 80. 18 and 19 are a front view and a rear view of the cover member 80. FIGS. 20A and 20B show the engagement between the housing 12 and the connector 20 using the cover member 80 in the medical electronic device 1. It is a figure which cancels a state. FIGS. 21A to 21D are diagrams showing the operation of pulling out the engaging claw 522 from the notch 541.

  The cover member 80 has a function of covering the connector mounting portion 13 including the insertion opening 132 of the device main body 10 when the connector 20 is mounted, and a function of separating the connector 20 shown in FIGS. 1 to 13 from the device main body 10. .

  The cover member 80 shown in FIGS. 14 to 19 is detachably attached to the device main body 10 so as to cover the connector mounting portion 13 (particularly, the insertion opening 132), and covers and protects the connector mounting portion 13. Can be stored. In the present embodiment, the cover member 80 is continuous with the electrode connection portion (terminal portion) 176 connected to the terminal portion 32 of the electrode 30 and the housing portion 11 in the device main body 10, and the battery housing portion 24 is Both the insertion slot 132 to be inserted is covered and protected.

  The cover member 80 is provided so as to protrude from the cover main body 82 covering the insertion opening 132 and both sides of the cover main body 82 on the opening 84 side in the mounting direction to the device main body 10, and partially cover both sides of the device main body 10. And an arm portion 86 arranged so as to cover it.

The cover main body 82 has a case shape having an opening 84 that opens on one side, and the connector mounting portion 13 (see FIG. 7) on the one end surface 12a side of the device main body 10 is inserted into the opening 84.
In this embodiment, the cover main body 82 is detachably fitted to the connector mounting portion 13 inserted into the opening 84. When the connector mounting portion 13 is inserted into the opening 84 and fitted to the connector mounting portion 13, the cover main body 82 has an opening edge 822 surrounding the opening 84 (see FIGS. 16 to 18). By contacting the one end surface 12a, the movement in the insertion direction is regulated. In the opening 84, as shown in FIG. 18, ribs 824 protrude from both side walls which are laterally separated from each other in a rectangular peripheral wall in a front view surrounding the opening 84, and extend in the depth direction on the bottom wall. An existing ridge 826 is provided. The ribs 824 and the ridges 826 engage with the outer surface of the connector mounting portion 13 inserted into the opening 84 to be in a detachable fitting state. In FIG. 18, the housing 12 of the device main body 10 in a state where the housing 12 is fitted to the cover member 80 is indicated by a broken line.

The arm portion 86 has a function of detaching the connector 20 attached to the device main body 10, that is, the electrode 30 connected to the device main body 10. The arm 86 is formed so as to be inserted into the notch 541, and can be arranged so as to fit into the notch 541.
The arm 86 has a function of releasing the engaged state between the window 542 and the engaging claw 522 by being inserted into the notch 541 and moving along the notch 541. The arm 86 is provided to protrude from the cover main body 82. In the present embodiment, the arm portion 86 is formed so as to protrude in the opening direction from a corner portion that is separated in the longitudinal direction in the opening portion 84 of the cover member 80.

  In the arm portion 86, at least a tip portion has a corner portion (a corner portion 12b composed of a bottom surface of the one end surface 12a and both side portions, which is separated in the longitudinal direction on the one end surface 12a (see FIGS. 7 and 8) of the device main body 10; 12c) is formed in an L-shaped cross section so as to cover each of them.

  Since the arm 86 is formed in an L-shaped cross section so as to cover the corners 12 b and 12 c of the device main body 10, the arm 86 serves as a guide when the cover member 80 is mounted on the connector mounting portion 13. Further, the arm 86 and the corners 12b and 12c are configured to engage with each other in two directions orthogonal to the mounting direction, and the one end surface 12a of the device main body 10 and the opening 84 of the opening 84 of the cover main body 82 are formed. You may hold | maintain in the state which contacted the edge part 822. In this case, the insertion opening 132 together with the connector mounting portion 13 is housed in the cover main body 82 and supported in a protected state. The engagement state between the cover member 80 and the device main body 10 by the arm portion 86 is released only by moving the cover member 80 in the withdrawal direction so as to separate the cover member 80 from the device main body 10.

  In the present embodiment, each of the arms 86 has an L-shape formed by one surface 862 and the other surface 864 extending in the opening direction of the connector body 22. The length between the other surface portions 864 positioned so as to sandwich both side surfaces of the device main body 10 corresponds to the width of the housing 12. Further, the width (horizontal length) of the one surface portion 862 covering the bottom surface side of the device main body 10 is configured to be substantially the same as or the same as the depth (horizontal length) of the cutout portion 541, The tip of the one surface portion 862 is formed so as to be inserted into the cutout portion 541.

  Each one surface portion 862 of the arm portion 86 on both sides has a pressing portion 863 which is inclined so as to approach each other from the distal end toward the proximal end (see FIG. 21).

  With this configuration, for example, as shown in FIG. 20A, when the connector 20 is detached from the device main body 10 to which the connector 20 is engaged and attached, the arm portions on both sides of the cover member 80 detached from the device main body 10. One surface portion 862 of the connector 86 is inserted into the cutout portion 541 from a direction (here, the front surface side) orthogonal to the mounting direction of the connector 20. FIG. 21A shows a state before the one surface portion 862 is inserted into the cutout portion 541. Further, when the one surface 862 is inserted into the notch 541, the other surface 864 functions as a guide when the one surface 862 is inserted into the notch 541. Then, the one surface portion 862 engages with the window portion 542 of the device main body 10, and the engaging claw portion 522 protruding in the notch portion 541 through the window portion 542 is moved from the window portion 542 to the housing 12. It presses inward, and as shown in FIG. 21B, presses in a direction to remove it from the frame portion 543 of the window portion 542.

  Then, the arm portion 86 is in a state where the one surface portion 862 is inserted into the notch portion 541 (see FIG. 20B). At this time, the one surface portion 862 deforms the engaging claw portion 522 by pressing the engaging claw portion 522 from the inside of the notch portion 541 in a direction to be disengaged from the frame portion 543 of the window portion 542 as shown in FIG. 21C. It is displaced in a direction separating from the part 541 and the window part 542. At this time, with the deformation of the engagement claw 522, the connector 20 moves in a direction to come off from the device main body 10. The engaging claw portion 522 is elastically deformed, displaced inside the device main body 10, disengages from the window portion 542, and can detach the connector 20 itself from the device main body 10.

  The embodiment of the invention has been described. The above description is an illustration of a preferred embodiment of the present invention, and the scope of the present invention is not limited to this. That is, the description of the configuration of the device and the shape of each part is merely an example, and it is apparent that various modifications and additions to these examples are possible within the scope of the present invention.

  INDUSTRIAL APPLICABILITY The medical electronic device according to the present invention has an effect of easily measuring a desired number of channels of an electrocardiogram according to a subject, and is useful as a Holter monitor.

DESCRIPTION OF SYMBOLS 1 Medical electronic device 10 Device main body 11 Housing part 12 Case 12a One end surface 12b, 12c Corner 13 Connector mounting part 132 Insertion opening (opening)
14 display section 15 event key 16 enter key 17 circuit section 20 connector 22 connector body 23 guide section 24 battery accommodating section 26 short-circuit prevention section 27 step 28 connection block 29 connector mounting confirmation section 30 electrode 32 terminal section 33 branch section 34 electrode section 36 electrode section 36 Guide lead part 50 Lock mechanism part 52 Engagement part 54 Engaged part 61 Channel indicating part 70 Waterproof member 72 Frame part 74 Projection 80 Cover member 82 Cover body 84 Opening 86 Arm part 172 Plus terminal connection part 174 Minus Terminal connection part 176 Electrode connection part 222, 822 Opening edge part 242 Tray part 246 Pole cutout part 30a Mounting surface part 30b Mounting surface part 522 Engagement claw part 541 Notch part 542 Window part 543 Frame part 722 Inner circumference part 724 Outer circumference part 862 One surface Part 863 pressing part 864 other Part B battery

Claims (2)

A medical electronic device that measures an electrocardiogram using an electrocardiogram electrode,
A device main body for measuring an electrocardiogram with a predetermined number of channels,
A connector that is provided on the electrocardiogram electrode, is detachably attached to the device main body, and connects the electrocardiogram electrode to the device main body,
Has,
The connector, when attached to the device body, has a channel indicator for indicating the number of channels to the device body,
Medical electronics. The device body has a housing portion that opens on one surface side,
In the accommodation unit, a circuit unit that has a device side terminal unit electrically connected to the electrocardiogram electrode, and that measures an electrocardiogram with the indicated number of channels, is provided.
The channel instruction unit is a protrusion provided to protrude from the connector, and when the connector is attached to the device main body, instructs the number of channels by contacting the circuit unit.
The medical electronic device according to claim 1.

Images