JP6747767B2 - connector - Google Patents

Description

The present invention relates to a connector.

For example, in a patient whose heart has ventricular fibrillation and is unable to send blood to the whole body, an external defibrillation attempting to remove the fibrillation of the heart by applying an electric shock in order to restore the normal movement of the heart. The motive is known.

The external defibrillator is, for example, as shown in Patent Document 1, an electric shock to a patient via an extracorporeal paddle or an attachment electrode and an extracorporeal paddle applied to the body surface or an attachment electrode attached to the body surface. And a defibrillator body that provides
A cable is led out from the extracorporeal paddle, and a connector is provided at the end of the cable. By inserting this connector into the defibrillator body, the extracorporeal paddle is electrically connected to the defibrillator body.

The defibrillator body gives an electric shock to the patient through the extracorporeal paddle by the extracorporeal paddle to perform the defibrillation process. The defibrillator body can acquire information (electrocardiogram ECG: Electrocardiogram) relating to the state of the patient's heart through the extracorporeal paddle.

For this reason, the connector for external paddle connection, which connects the defibrillator body and external paddle, transmits a high-voltage pin to which a high voltage is applied to supply an electric shock, and a control signal or ECG for the electric shock. It has a plurality of pins that transmit signals having different voltage levels, such as a plurality of signal pins that operate. These pins are used when the connector is inserted into the defibrillator body (specifically, in the socket on the defibrillator body side), and on the defibrillator body side, the corresponding terminals of the pins on the connector side, respectively. Is connected to the socket terminal. Plural pins such as high voltage pins and signal pins are inserted into the concave socket body of the socket to which the connector is connected, and are connected in a concave portion provided at the end face on the insertion direction side in the connector main body. It is arranged.

JP, 2007-222659, A

However, in the conventional connector for external paddle connection, since the plurality of signal pins (terminals) are collectively arranged in one recessed portion, fingers, dust, etc. may be placed between the signal pins in this recessed portion. Foreign matter easily enters. As a result, there is a problem that the signal pin bends and comes into contact with another signal pin, or a foreign substance remains between the signal pins.

Also, because multiple signal pins are arranged in the recessed part of the connector, if the corresponding socket terminals are misaligned when this connector is inserted into the socket, the sockets on the socket side The terminals may get inside and damage the signal pins.

The present invention has been made in view of the above points, and an object of the present invention is to provide a connector that has a plurality of terminals to be connected and that can be suitably connected to a mating connector while preventing foreign matter from entering between the terminals. ..

One aspect of the connector of the present invention is
A defibrillator connector that is attached to the end of a connection cord that connects a pair of extracorporeal paddles in a single connection and that connects to a mating connector provided on the defibrillator,
A connector body that is inserted into and mated with the mating connector in a direction orthogonal to the mounting direction of the connection cord ,
A plurality of terminals that are arranged on the connector body and that are respectively connected to terminals of the mating connector by fitting the connector body and the mating connector;
Have
The connector body is arranged on the outer peripheral side of the connector body so as to surround the connector body, and is fitted around the connector body by rotating in the circumferential direction to engage with the mating connector side. A rotation lock body that locks the combined state is provided,
The plurality of terminals include a first terminal and a plurality of second terminals having different types and outer diameters from the first terminal,
The connector body is provided inside the rotation lock body so as to open at a surface on the insertion direction side to the mating connector, and the plurality of second terminals are arranged inside and extend in the insertion direction. Has a concave portion,
A configuration is adopted in which a partition wall portion that partitions the plurality of second terminals is provided in the concave portion.

One aspect of the connector device of the present invention is
With the connector of the above configuration,
A socket connector provided on the defibrillator, into which the connector is inserted and fitted,
Have
The socket connector has a socket body into which the connector body is inserted in an insertion recess formed in a concave shape,
The socket body is
A socket-side first terminal and a socket-side second terminal that are arranged in the insertion recess and correspond to the first terminal and the plurality of second terminals of the connector, respectively;
And a cover wall portion that is disposed so as to surround the socket-side terminal and the socket-side first terminal in the insertion recessed portion, and that is inserted into a space partitioned by the partition wall portion in the recessed portion of the connector.

According to the present invention, in a configuration having a plurality of terminals to be connected, foreign matter does not enter between the terminals, and it is possible to preferably connect to a mating connector.

Front view of an external defibrillator to which a connector according to an embodiment of the present invention is applied 1 is a right side view of an external defibrillator to which a connector according to an embodiment of the present invention is applied. A side view of the connector device showing a state in which the paddle connector shown in FIG. 2 is removed from a mating connector. The figure which looked at the connector device shown in FIG. 3 from the back side of a paddle connector. Sectional view taken along the line AA of FIG. Front view of a paddle connector to which a connector according to an embodiment of the present invention is applied Front view of mating connector connected to paddle connector Partial cross-sectional view showing the positional relationship in the insertion direction of the partition wall portion and each terminal in the connector

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

FIG. 1 is a front view of an external defibrillator to which a connector according to an embodiment of the present invention can be applied, and FIG. 2 is a right side view of the same.

An external defibrillator 10 shown in FIGS. 1 and 2 includes an external defibrillator body (hereinafter referred to as “defibrillator body”) 20, a pair of external paddles (paddles) 30, 40, and a paddle. It has a connector device 60 for connecting the connection cord 50 connected to 30, 40 to the defibrillator body 20.

As shown in FIGS. 1 and 2, the paddles 30 and 40 have electrode portions (only the electrode portion 31 is shown in FIG. 2) and handle portions 32 and 42. The electrode portion 31 is formed such that the lower surface thereof has a contact surface (not shown) for contacting the body surface of the patient. The handle parts 32 and 42 are integrated with the electrode part 31 (only the electrode part 31 is shown in FIG. 2), and are provided so as to project from the upper surface which is the surface opposite to the contact surface from the electrode part 31. .. Although not shown, the handle parts 32 and 42 are provided with a charging switch and an energizing switch.

The charging switch outputs a signal indicating a charging instruction to the control unit when pressed by the defibrillator. In response to this signal, the control unit controls the defibrillation pulse output circuit unit to charge the electric energy from the electric energy supply unit. In addition, the energizing switch outputs a signal for starting energization to the control unit via the connector device 60 when pressed by the defibrillator. Accordingly, the control unit causes the defibrillation pulse output circuit unit to start energization and outputs the defibrillation pulse to the paddles 30 and 40.

Further, the handle portions 32 and 42 are formed in an L shape in consideration of the ease of holding by a defibrillator, and a connection cord 50 is extended to each tip portion thereof. Here, the connection cord 50 is a curl cord curled in a spiral shape, and is a retractable cord. A paddle connector (connector) 100 is attached to an end of the connection cord 50. The connector 100 connects the paddles 30 and 40 to the defibrillator body 20 by inserting the connector 100 into the defibrillator body 20 (specifically, a socket that is a mating connector). A detailed description of the connector 100 will be given later together with a description of the connector device 60.

The paddles 30 and 40 shown in FIGS. 1 and 2 are detachably accommodated in a paddle table 23 provided on the upper surface of the defibrillator body 20, and when in use, the handle portions 32 and 42 are grasped and the paddle table is held. It can be pulled out from 23 and used.

The external defibrillator body 20 discharges the energy charged inside the defibrillator body 20 as a high-voltage (high-voltage) defibrillation pulse from the extracorporeal paddle into the patient's body to cause an electric shock to the myocardium of the patient. Is given.

The defibrillator body 20 has a display unit 25 and an internal circuit including a control unit (not shown), an electric energy supply unit, a defibrillation pulse output circuit unit, and a biological information acquisition unit therein.

The electric energy supply unit has an AC power supply or a battery, and performs power supply (supply of electric energy) from the AC power supply or the battery to each unit in the defibrillator body.

The control unit is an arithmetic processing unit such as a CPU (Central Processing Unit) and controls the operation of each unit inside the external defibrillator. For example, the control unit controls the defibrillation pulse output circuit unit by the defibrillation processor operating the operation unit, the energizing switch or the charging switch of the paddles 30 and 40, and the defibrillation pulse output circuit unit is controlled from the electric energy supply unit. The supplied electric energy is used to generate and output a defibrillation pulse that causes an electric shock.

The operation unit includes a charging switch provided on the defibrillator body 20, an energizing switch equipped on the handle portions 32, 42 of the extracorporeal paddles 30, 40, and the like. The charging switch has the same effect as the charging switches of the paddles 30 and 40, and when pressed by the defibrillator, outputs a signal indicating a charging instruction to the control unit. In response to this signal, the control unit instructs the defibrillation pulse output circuit unit to be charged with the electric energy from the electric energy supply unit. Further, the energizing switch has the same effect as the energizing switches of the paddles 30 and 40, and when pressed by the defibrillator, outputs a signal for starting energization to the control unit via the connector device 60. To do. In response to this signal, the control unit causes the defibrillation pulse output circuit unit to start energization.

Further, the control unit acquires the biological information of the patient (electrocardiogram ECG or the like) input by the paddle guidance of the extracorporeal paddles 30 and 40, that is, the measurement signal via the connector device 60 and displays it on the display unit 25. Perform processing, etc. The display unit 25 displays the patient's electrocardiogram (measurement signal) and the like input via the paddles 30 and 40 and the connector device 60 under the control of the control unit.

The defibrillation pulse output circuit unit generates a high voltage by boosting the power supply voltage (electric energy) by a high-voltage transformer (not shown) under the control of the control unit when the charging switch is pressed. Charging energy is obtained by charging a high voltage capacitor (not shown) with a voltage. This charging energy is the output energy of the defibrillation pulse, and the level thereof can be manually set by providing an output energy setting knob portion in the operation portion and operating this knob portion. In addition, the defibrillation pulse output circuit unit generates a high-pressure defibrillation pulse from the charging energy when the energizing switch is pressed, and the defibrillation pulse is transmitted through the connector device 60 to the external paddles 30, 40. To the electrode section (only the electrode section 31 is shown in the figure).

The internal circuit of the defibrillator body 20 is connected via a connector device 60 to the internal circuits of the extracorporeal paddles 30 and 40 having an energizing switch, an electrode portion (only the electrode portion 31 is shown in FIG. 1) and the like. As described above, the connector device 60 not only connects the paddles 30 and 40 to the defibrillator body 20 via the connection cord 50 but also connects the internal circuit of the defibrillator body 20 and the internal circuit of the paddles 30 and 40. Connect.

<Structure of connector device 60>
FIG. 3 is a side view of the connector device showing the connector shown in FIGS. 1 and 3 removed from a mating connector, and FIG. 4 is a view of the connector device shown in FIG. 5 is a cross-sectional view of the connector device shown in FIG. 4 taken along the line AA. In addition, in FIG. 4 and FIG. 5, the position of the rotation lock body is located at the unlocked position. FIG. 6 is a front view of a paddle connector to which the connector according to the embodiment of the present invention is applied, and the paddle connector is viewed from the insertion direction side. Further, FIG. 7 is a front view of a mating connector connected to the paddle connector.

As shown in FIGS. 3 and 4, the connector device 60 includes a socket (a mating connector) 70 attached to the defibrillator body 20 and a paddle connector 100 that is detachable from the socket 70.

The paddle connector 100 is provided at the end of the connection cord 50 connected to the paddles 30 and 40, is inserted into the socket body 72, and fits with the socket body 72.

As shown in FIGS. 3 to 6, the paddle connector 100 includes a connector body 110 that is inserted into and fitted into the insertion recess 73 of the socket body 72, a first terminal 130 and a second terminal 130 that are disposed in the connector body 110. It has a plurality of paddle connector side connection terminals including terminals 140 and a rotation lock body 150.

The connector body 110 is an insulator formed in a columnar shape, here a columnar shape, and a portion on one end side (a portion on the front side and a portion on the insertion direction side) is inserted into the insertion recess 73 of the socket body 72. It is an insertion main body, and is connected to the connection cord 50 at a portion on the other end portion side (a portion on the opposite side to the insertion direction and also referred to as a base end portion).

On the outer periphery of the connector body 110 (specifically, the insertion body portion), a cylindrical rotation lock body 150 is rotatably mounted in one of the circumferential directions (lockable position) from the lock position.

The rotation lock body 150 locks and holds in the fitted state when the connector 100 is inserted and fitted in the socket 70. It should be noted that the rotation lock body 150 has a protrusion 153 (see FIG. 8) provided on the base end side, which is an end opposite to the insertion direction, with respect to the connector body 110, and is provided around the outer periphery of the connector body 110. The groove 118 is formed so as to be loosely fitted in the groove 118, and is mounted so as to be spaced apart from the outer peripheral surface of the connector body 110 on the insertion direction side via the protrusion 153.

The rotation lock body 150 is biased toward the lock position by a biasing member (not shown) on the other side of the connector body 110 in the outer peripheral direction. At the end of the rotation lock body 150 on the insertion direction side, a claw portion 151 protruding inward is provided. The claw portion 151 loosely fits into the key groove portion 77 (see FIGS. 3 and 7) of the socket body 72 when the connector body 110 is inserted into the insertion recess 73 of the socket body 72. The claw portion 151 is located at the lock position with respect to the connector body 110 and is rotatable in one side in the circumferential direction, but is in a state of being biased by the biasing member toward the lock position.

As shown in FIGS. 5 and 6, a first concave portion 112 and a second concave portion 114 that open in the insertion direction are formed on the end surface of the connector body 110 on the insertion direction side.

Inside each of the first concave portion 112 and the second concave portion 114, different types of first terminals 130 and second terminals 140 are arranged to extend in the insertion direction. Here, the different types of terminals may be terminals having different shapes for the first terminal 130 and the second terminal 140, or terminals for transmitting different types of signals between the first terminal 130 and the second terminal 140. It may be. Here, the first terminal 130 and the second terminal 140 will be described as terminals that transmit signals having different voltage levels.

The first terminal 130 is provided in the first concave portion 112 so as to project from the bottom surface portion, and the first terminal 130 is arranged to extend in the insertion direction. In the present embodiment, two first concave portions 112 are provided, and one first terminal 130 is arranged in each of the first concave portions 112.

In the second concave portion 114, a plurality of second terminals 140 are provided so as to project from the bottom surface portion, and the plurality of second terminals 140 are arranged to extend in the insertion direction.

The first concave portion 112 and the second concave portion 114 are formed with different opening shapes so that they cannot be inserted when the connector body 110 is inserted in the insertion concave portion 73 of the socket body 72 by mistake.

In the present embodiment, the first concave portions 112 have a circular opening shape, and two first concave portions 112 are formed in a semicircular region that is half the circular end surface of the connector body 110 on the insertion side.

In addition, the second concave portion 114 is formed in the semicircular region of the other half of the circular end surface on the insertion side of the connector body 110, and has a trapezoidal opening shape.

The first terminal 130 and the second terminal 140 are rod-shaped bodies having conductivity. The first terminal 130 and the second terminal 140, when the connector main body 110 is inserted and fitted into the insertion recess 73, with respect to the socket side terminals (socket side first terminal and second terminal 74, 75). , Is formed so as to be connectable in the extending direction of the terminals on the socket side. Here, the first terminal 130 and the second terminal 140 are pin-shaped terminals having different outer diameters.

The first terminal 130 and the second terminal 140 are connected to the contact surfaces of the electrode portions of the paddles 30 and 40 (see FIGS. 1 and 2) via the connection cord 50. The first terminal 130 is a high-voltage pin that transmits a high-voltage defibrillation pulse that is an electric shock, and is thicker than the second terminal 140.

The second terminal 140 is a terminal that transmits a signal different from the defibrillation pulse, and transmits a signal whose voltage level is different from that of the signal transmitted from the first terminal 130. Specifically, each of the plurality of second terminals 140 has a control system signal such as an operation (control signal) for starting energization from the energizing switch, a operation (control signal) for starting charging from the charging switch, and the biological information. It is a signal pin for transmitting a signal indicating (electrocardiogram) and the like. As described above, in the present embodiment, the first terminal 130 is a terminal for transmitting a defibrillation pulse for electric shock, whereas the plurality of second terminals 140 are other than the defibrillation pulse. A signal, here, a signal of a control system such as charging operation for electric shock, energizing operation (electric shock applying operation), and a signal (measurement signal) indicating measured biometric information such as an electrocardiogram are used as terminals.

The second terminals 140 are arranged in a plurality of rows within the second concave portion. Here, the second terminals 140 are arranged in the trapezoidal concave portion 114 in rows along the upper and lower bases of the trapezoid, and a plurality of second terminals 140 are arranged in each row.

A partition wall portion 120 that partitions the plurality of second terminals 140 is disposed inside the second recessed portion 114 in which the second terminals 140 are disposed. The partition wall portion 120 partitions each row of the second terminals 140 arranged in a plurality in the plurality of second terminals 140 in the horizontal direction here.

FIG. 8 is a partial cross-sectional view showing the positional relationship in the insertion direction of the partition wall portion and each terminal in the paddle connector.

As shown in FIG. 8, the end portion 121 of the partition wall portion 120 on the insertion direction side is positioned on the insertion direction side (tip side) with respect to the insertion direction side end 142 of the second terminal 140 (position indicated by line L3). (Position indicated by line L2). Further, the end portion 121 of the partition wall portion 120 is located on the rear side with respect to the opening edge (the position indicated by the line L1) of the concave portion 114, that is, the opening edge of the concave portion 114 (the surface on the insertion direction side of the connector body 110). ) Located away from.

Furthermore, the end portion 142 of the second terminal 140 is located on the back side (shown by the line L3) of the insertion direction side end 132 of the first terminal 130 (the position shown by the line L2), that is, the concave portion 114. Located away from the opening edge.

Thus, when the connector body 110 is inserted into the insertion recess 73 of the socket body 72 to connect both terminals, first, the first terminal 130 whose end 132 is located on the most insertion direction side is connected, Then, the second terminal 140 becomes connectable. Note that, here, the end portion 121 of the partition wall portion 120 on the insertion direction side is located at the same position as the terminal 132 on the insertion direction side of the first terminal 130, from the opening edge of the concave portions 114 and 112 toward the inner side. (Position indicated by line L2).

As shown in FIGS. 3 and 5, the socket 70 includes a mounting plate portion 71, a socket main body 72 protruding from one surface of the mounting plate portion 71, and fitted with the paddle connector 100, and a socket main body 72. The socket-side first terminal 74 and the plurality of socket-side second terminals 75 (see FIG. 7) are provided.

In the socket 70, the socket main body 72 is inserted into the opening 22 formed in the side surface portion 21 of the housing of the defibrillator main body 20 (see FIGS. 1 and 2 ), and one surface of the mounting plate portion 71 is a side surface portion. It is fixed inside 21. As a result, the socket 70 is attached to the defibrillator body 20 with the socket body 72 protruding outside the side surface portion 21.

The socket main body 72 is an insulator, and as shown in FIGS. 5 and 7, is formed in a columnar shape, here a columnar shape, having an insertion recess 73 opened to the one end face side (front side).

On the outer periphery of the socket main body 72, a key groove portion 77 in which the claw portion 151 of the rotation lock body 150 on the paddle connector side is loosely fitted is formed. The key groove portion 77 is curved in a spline shape in the insertion direction from the opening side, and is bent in the circumferential direction on the back side (insertion direction side) of the socket body 72. Thereby, the key groove portion 77 guides the claw portion 151 of the rotation lock body 150 to the bent portion (corresponding to the lock position) as the connector body 110 of the paddle connector 100 is inserted into the insertion recess 73. Restricts movement in the pull-out direction (opposite to the insertion direction).

The connector body 110 of the paddle connector 100 is inserted and fitted into the insertion recess 73. The socket body 72 is integrally formed with the mounting plate 71 by an insulating material such as resin.

On the bottom surface of the insertion recess 73, the socket-side first terminal 74 and the socket-side second terminal 75 project toward the front side in a state of being surrounded by the terminal covering wall portions 722 and 724 and at positions separated from each other. Has been done. The socket side first terminal 74 and the socket side second terminal 75 are arranged corresponding to the arrangement positions of the first terminal 130 and the second terminal 140 of the paddle connector 100.

The terminal covering wall portion 722 is formed corresponding to the first concave portion 112, and is inserted into the first concave portion 112 when the connector body 110 is inserted into the insertion concave portion 73. At this time, the socket-side first terminal 74 is fitted and connected to the first terminal 130.

The terminal covering wall portion 724 is formed corresponding to the second recessed portion 114 partitioned by the partition wall portion 120, and is inserted between the partition wall portions 120 when the connector body 110 is inserted into the insertion recess 73. .. At this time, the socket-side second terminals 75 are fitted and connected to the corresponding second terminals 140, respectively.

In other words, the arrangement positions of the socket-side first terminal 74 covered with the terminal covering wall portion 722 and the socket-side second terminal 75 covered with the terminal covering wall portion 724 are the first terminal 130 and the first terminal 130 of the paddle connector 100. It is a position corresponding to the arrangement position of the concave portion 112, the second terminal 140, and the second concave portion 114.

Two socket-side first terminals 74 coated with the terminal coating wall portion 722 are arranged in a half-circular region of the insertion recess 73 having a circular opening shape, and the two socket-side first terminals 74 are disposed in the first recessed portion 112 of the connector body 110. It corresponds to the first terminal 130 of. A plurality of socket-side second terminals 75 coated with the terminal coating wall portion 724 in the semicircular region of the other half are arranged corresponding to the formation positions of the second terminals 140 in the second recess 114. ..

The socket-side first terminal 74 and the socket-side second terminal 75 are formed to be connectable to the paddle connector-side first terminal 130 and the second terminal 140 that move in the insertion direction. Here, the socket-side first terminal 74 and the socket-side second terminal 75 are rod-shaped socket terminals provided with tubular contact portions whose ends on the opening side are formed in a tubular shape.

The socket-side first terminal 74 and the socket-side second terminal 75 are connected to the internal circuit of the defibrillator body 20. Here, the socket-side first terminal 74 is a terminal that transmits a high-voltage defibrillation pulse that causes an electric shock, and is connected to the defibrillation pulse output circuit unit.

The socket-side first terminal 74 and the socket-side second terminal 75 transmit signals transmitted by the corresponding first terminal 130 and second terminal 140. That is, the socket-side second terminal 75 is a terminal that transmits a signal different from the defibrillation pulse, and transmits a signal having a different voltage level from the signal transmitted by the socket-side first terminal 74. Here, the plurality of socket-side second terminals 75 transmit a signal different from the defibrillation pulse, and control signals such as an energization start control signal from the energization switch and a charging start control signal from the charging switch. It is a terminal for transmitting signals and measurement signals such as biological information (electrocardiogram), and is connected to the control unit.

<Connecting operation of the paddle connector 100 and the socket 70>
When connecting the socket 70 and the paddle connector 100, the front end (the end on the insertion direction side) of the connector body 110 is aligned with the opening edge of the insertion recess 73 of the socket body 72, To insert. At that time, the claw portion 151 of the rotation lock body 150 is inserted into the key groove portion 77.

When the connector body 110 is inserted into the insertion recess 73, the terminal covering wall 722 is inserted into the first recess 112, and the terminal covering wall 724 is inserted into the second recess 114.

Then, after the first terminal 130 is connected to the socket-side first terminal 74, the second terminal 140 is connected to the socket-side second terminal 75.

With the insertion of the connector body 110 into the insertion recess 73, the claw portion 151 of the rotation lock body 150 enters the key groove portion 77. Further, when the connector main body 110 is inserted into the inner side of the insertion concave portion 73, the claw portion 151 of the rotation lock body 150 is guided by the key groove portion 77 to resist the urging force of the urging member (not shown) in the circumferential direction. In one direction (the spline direction guided by the key groove 77).

Next, the first terminal 130 and the second terminal 140 move to a position where they are connected to the socket-side first terminal 74 and the socket-side second terminal 75. With this movement, the claw portion 151 located on the outer peripheral side of the connector main body 110 is located at a position bent in the circumferential direction after moving the spline-shaped portion in the key groove portion 77. Then, the guide by the spline-shaped portion of the key groove portion 77 is released with respect to the claw portion 151, and the claw portion 151 moves within the bent portion along the circumferential direction by the biasing force and returns to the locked position. In this state, the claw portion 151 is restricted from moving in the pull-out direction (the direction opposite to the inserting direction) by the bent portion. As a result, the connector body 110 engages with the socket body 72 via the rotation lock body 150 so as not to come off from the socket body 72, and the paddle connector 100 is fixed to the socket 70.

By connecting the socket 70 and the paddle connector 100, a high-voltage defibrillation pulse (high-voltage signal) from the defibrillator body 20 side to the extracorporeal paddles 30 and 40 side, transmission of a control signal, and acquisition of a signal indicating an electrocardiogram. Transmission etc. becomes possible. That is, by connecting the socket 70 and the paddle connector 100 to each other, a path for defibrillation pulse and a path for control and electrocardiogram are established respectively. When the paddle connector 100 is detached from the socket 70, the rotation lock body 150 is rotated against the biasing force so that the claw portion 151 can be inserted from the bent portion to the spline portion (lock releaseable position. ) To move. Then, the paddle connector 100 can be removed from the defibrillator body 20 by pulling out the paddle connector 100 from the socket in the direction opposite to the insertion direction.

In the connector device 60, the paddle connector 100 has a connector body 110 that is inserted into and fitted into the socket 70, a first terminal 130, and a plurality of second terminals 140. The first terminal 130 and the second terminal 140 are respectively connected to the socket-side first terminal 74 and the socket-side second terminal 75 of the socket 70 by fitting the connector body 110 and the socket 70. The second terminal 140 transmits a signal of a type different from the signal transmitted by the first terminal 130.

The connector main body 110 is provided with an opening on the surface on the insertion direction side into the socket 70, and has a second concave portion 114 inside which extends in the insertion direction and in which the plurality of second terminals 140 are arranged. A partition wall portion 120 that partitions the plurality of second terminals 140 is provided in the second concave portion 114. Even if a plurality of second terminals 140 are arranged in the second concave portion 114, the partition wall portion 120 prevents foreign matters such as dust and fingers from entering between the second terminals 140. Further, even when the terminals on the socket 70 side (the socket-side first terminal 74, the socket-side second terminal 75) accidentally try to enter between the second terminals 140 when connecting to the socket 70, the partition wall portion 120 Thus, it is possible to prevent the intrusion and prevent the second terminal 140 from being damaged.

In addition, in the paddle connector 100, the end portion 132 of the first terminal 130 on the insertion direction side is located on the insertion direction side of the end portion 142 on the insertion direction side of the plurality of second terminals 140. That is, the end portions 142 of the plurality of second terminals 140 on the insertion direction side are located deeper than the end portions 132 of the first terminal 130 on the insertion direction side.

On the other hand, the socket-side first terminal 74 and the socket-side second terminal 75 of the socket 70 are arranged at positions having substantially the same depth from the opening edge of the insertion recess 73.

Accordingly, the first terminal 130 and the plurality of second terminals 140 on the paddle connector 100 side are inserted into the mating terminals (socket side first terminal 74, socket side second terminal 75) in order according to type. Connected.

In this configuration, the insertion depth is necessarily deep in the first terminal 130 and shallow in the second terminal 140 disposed in the back, so that the first terminal 130 is also defined when the conduction of the second terminal 140 is not recognized. It can be determined that it has not been inserted to the depth of. This allows the defibrillator body 20 side to recognize how deeply the paddle connector 100 is inserted into the socket 70.

The embodiments disclosed this time are to be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description but by the claims, and is intended to include meanings equivalent to the claims and all modifications within the scope.

The embodiments of the present invention have been described above. The above description is an example 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 one example, and it is obvious that various modifications and additions can be made to these examples within the scope of the present invention.

Even if the connector according to the present invention has a plurality of terminals to be connected, it has an effect that foreign matter does not enter between the terminals and can be preferably connected to the mating connector, and connects the defibrillator and the paddle. It is useful as a paddle connector.

10 external defibrillator 20 defibrillator body 23 paddle stand 25 display section 31 electrode section 50 connection cord 60 connector device 70 socket 71 mounting plate section 72 socket body 73 insertion recess 74 socket side first terminal 75 socket side first 2 terminals 77 key groove portion 100 paddle connector 110 connector body 112 first concave portion 114 second concave portion 120 partition wall portion 121 end portion on insertion side 130 first terminal 132, 142 end portion 140 second terminal 150 rotation lock body 151 Claws 722, 724 Cover wall

Claims (6)

A defibrillator connector that is attached to the end of a connection cord that connects a pair of extracorporeal paddles in a single connection and that connects to a mating connector provided on the defibrillator,
A connector body that is inserted into and mated with the mating connector in a direction orthogonal to the mounting direction of the connection cord ,
A plurality of terminals that are arranged on the connector body and that are respectively connected to terminals of the mating connector by fitting the connector body and the mating connector;
Have
The connector body is arranged on the outer peripheral side of the connector body so as to surround the connector body, and is fitted around the connector body by rotating in the circumferential direction to engage with the mating connector side. A rotation lock body that locks the combined state is provided,
The plurality of terminals include a first terminal and a plurality of second terminals having different types and outer diameters from the first terminal,
The connector body is provided inside the rotation lock body so as to open at a surface on the insertion direction side to the mating connector, and the plurality of second terminals are arranged inside and extend in the insertion direction. Has a concave portion,
A partition wall portion for partitioning the plurality of second terminals is provided in the concave portion.
connector. An end portion of the partition wall portion on the insertion direction side is located on the insertion direction side of the second terminal, and is located on the back side of the opening edge of the concave portion.
The connector according to claim 1. Wherein the first terminal is a terminal for transmitting defibrillation pulses, said second terminal, said defibrillation pulse is a terminal for transmitting different signals,
The connector according to claim 1 or 2. The concave portion is a trapezoidal concave portion,
The connector body has an opening on the surface on the insertion direction side, and has another circular concave portion whose opening shape is different from the concave portion,
The first terminal is arranged to extend in the insertion direction in the circular concave portion.
The connector according to any one of claims 1 to 3. An end portion of the first terminal on the insertion direction side is located on the insertion direction side of an end portion of the second terminal on the insertion direction side,
The connector according to any one of claims 1 to 4. A connector according to any one of claims 1 to 5,
A socket connector provided on the defibrillator, into which the connector is inserted and fitted,
Have
The socket connector has a socket body into which the connector body is inserted in an insertion recess formed in a concave shape,
The socket body is
A socket-side first terminal and a socket-side second terminal that are arranged in the insertion recess and correspond to the first terminal and the plurality of second terminals of the connector, respectively;
A cover wall portion that is disposed so as to surround the socket-side terminal and the socket-side first terminal in the insertion recessed portion, and that is inserted into a space partitioned by the partition wall portion within the recessed portion of the connector;
With
Connector device.

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