JP2010172503A - Nurse call system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect not only the drop of a nurse call slave unit from a distributor but also the drop of a mat sensor when the mat sensor and the nurse call slave unit are connected in parallel from the distributor which is connected to a wall-embedded slave unit. <P>SOLUTION: A first resistance 220 arranged in the wall-embedded slave unit 100 and a second resistance 420 arranged in a hand shape slave unit 140 are serially connected through the use of wiring via the distributor 120 and the mat sensor 160 from the wall-embedded slave unit 100 to the hand shape slave unit 140 via the distributor 120 again, and made as resistance for the voltage dividing of a power source voltage Vcc. Thus, when both the hand shape slave unit 140 and the mat sensor 160 are not dropped from the distributor 120, a closed circuit is formed, where an electric current is made to flow from a power source 200 to the ground via the two resistance 220, 420. When one of the hand shape slave unit 140 and the mat sensor 160 is dropped, the closed circuit is not formed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a nurse call system for calling a nurse in accordance with a call instruction from an electronic device having a nurse call function or a nurse call slave.

  In general, a nurse call system is used in hospitals and care facilities. The nurse call system is used when a patient at a hospital needs nursing support or when a caregiver at a care facility needs help from a caregiver (hereinafter simply referred to as “patient”). Is called a nurse or a caregiver (hereinafter simply referred to as “nurse”) by pressing a call button or the like.

  Many nurse call systems are installed in bedside walls such as nurse call cordless handsets installed in bedsides, toilets, bathrooms, etc., nurse call parent machines installed in nurse centers, and sickrooms and nursing rooms. It is configured to include a wall-embedded handset and a corridor lamp installed near the entrance of each room such as a hospital room or a nursing room.

  Nurse call cordless handsets include hand-shaped cordless handsets that call nurses by pressing call buttons, and hand-push buttons. Further, the nurse call slave unit is connected to the wall-embedded slave unit by a cable. As a technique related to the nurse call slave unit, there is known a technique that, when the nurse call slave unit is dropped from the wall-embedded slave unit, the nurse call master unit notifies the drop call (for example, Patent Document 1). See).

  Also, a mat equipped with a weight sensor is laid on the floor under the bed, and by detecting that the patient has got on the mat, an alarm indicating the patient's heel (or falling from the bed) is output. A mat sensor is also provided. In addition, a mat equipped with a weight sensor is placed on the patient's upper body side on the bed, and when the patient raises his / her body and the mat stops weighting, an alarm indicating that the patient has been raised is output. There is also a mat sensor designed as described above.

  Also, a distributor is known that makes it possible to connect a nurse call slave and a mat sensor to a wall-embedded slave (see, for example, Patent Documents 2 and 3). FIG. 4 is a diagram showing an example in which the wall-embedded handset 2, the hand-type handset 3 and the mat sensor 4 are connected using the conventional distributor 1. As shown in FIG. 4, the wall-embedded slave unit 2 includes a power supply 5 that supplies a predetermined voltage Vcc and a resistor 6 that drops the voltage Vcc supplied from the power supply 5. The distributor 1 distributes the current path from the wall-embedded slave unit 2 to the hand-type slave unit 3 and the mat sensor 4.

  The hand-type slave unit 3 includes a resistor 7 that drops the voltage Vcc supplied from the power source 5 and a switch 8 that is turned on when the patient presses the call button of the hand-type slave unit 3. Yes. The resistor 7 and the switch 8 are connected in parallel between the resistor 6 and the ground. Here, the resistance value of the switch 8 is extremely small. The mat sensor 4 includes a switch 9 that is turned on when a change in weight is detected by a weight sensor (not shown). The switch 9 is connected in series with the resistor 6 between the resistor 6 and the ground. Here, the resistance value of the switch 9 is extremely small.

  In the configuration as described above, by referring to the voltage appearing at the end point 10 (node on the opposite side of the power source 5 of the resistor 6) of the wall-embedded slave unit 2, the switch 8 of the hand-type slave unit 3 is turned on / off. The off state and the on / off state of the switch 9 of the mat sensor 4 can be determined. That is, when the switch 8 of the hand-type slave unit 3 and the switch 9 of the mat sensor 4 are in the OFF state, the power source voltage Vcc is distributed to the end point 10 of the wall-embedded slave unit 2 by the resistors 6 and 7 connected in series. A pressed voltage value is generated.

  In this state, for example, when the switch 8 is turned on by the patient pressing the call button of the hand-type slave unit 3, the end point 10 is short-circuited to the ground via the switch 8, so that the voltage at the end point 10 is zero. A close value. On the other hand, when the switch 9 is turned on when a change in weight is detected by the weight sensor, the end point 10 is short-circuited to the ground via the switch 9, so that the voltage at the end point 10 is close to zero.

  Thus, the ON state of the switches 8 and 9 is detected depending on whether or not the voltage at the end point 10 is close to zero. When the ON state of the switches 8 and 9 is detected by the wall-embedded handset 2, call signals are transmitted from the wall-embedded handset 2 in the order of the corridor lamp and the nurse call base unit. Informed by the nurse.

JP-A-8-242303 JP 2002-165845 A JP 2008-104652 A

  However, the above-described conventional nurse call system has the following problems to be solved. That is, in the wall-embedded slave unit 2, it can be detected that the hand-type slave unit 3 has dropped from the distributor 1, but it cannot be detected that the mat sensor 4 has fallen from the distributor 1.

  First, consider a case where the hand-type slave unit 3 is dropped from the distributor 1. Before the hand-type slave unit 3 is dropped, a current flows from the power source 5 to the ground through the resistors 6 and 7 (a current path is formed), and the power voltage Vcc by the resistors 6 and 7 is applied to the end point 10. Pressure is generated. On the other hand, after the hand-type slave unit 3 is dropped, a current path that flows from the power source 5 through the resistor 6 to the ground is not formed. That is, the voltage appearing at the end point 10 is different before and after the dropout, and the voltage after the dropout is not a value close to zero when either of the switches 8 and 9 is in the on state. Thus, it is possible to detect that the hand-type slave unit 3 has dropped from the distributor 1.

  Next, consider a case where the mat sensor 4 is dropped from the distributor 1. Before the mat sensor 4 is dropped, a current flows from the power source 5 through the resistors 6 and 7 to the ground (a current path is formed), and the power voltage Vcc divided by the resistors 6 and 7 is applied to the end point 10. Has occurred. On the other hand, even after the mat sensor 4 is removed, current flows from the power source 5 through the resistors 6 and 7 to the ground. That is, since the voltage appearing at the end point 10 has the same value before and after dropping, it cannot be detected that the mat sensor 4 has dropped from the distributor 1.

  The present invention has been made to solve such a problem. When a mat sensor and a nurse call slave unit are connected in parallel from a distributor connected to a wall-embedded slave unit, the distributor It is an object of the present invention to be able to detect not only that the nurse call slave has dropped but also that the mat sensor has dropped.

  In order to solve the above-mentioned problems, in the present invention, a nurse is connected to a wall-embedded slave unit, and a nurse call slave unit and an electronic device having a nurse call function are connected in parallel from the distributor. In the call system, the wall-embedded slave unit includes a power source for supplying a predetermined voltage and a first resistor having one end connected to the power source, and the nurse call slave unit is connected to the distributor from the wall-embedded slave unit. A second resistor connected in series with respect to the first resistor between the other end of the first resistor and the ground by wiring connected to the nurse call child device through the electronic device and the distributor. I have to.

  According to the present invention configured as described above, when neither the electronic device nor the nurse call slave unit is dropped from the distributor, a current flows from the power source to the ground through the first resistor and the second resistor. A current path (closed circuit) is formed. On the other hand, when at least one of the electronic device and the nurse call slave unit is disconnected from the distributor, a current path through which current flows from the power source to the ground through the first resistor and the second resistor is not formed. The tip of the resistor is the open end. That is, the other end side of the first resistor is in the case where neither the electronic device nor the nurse call slave has dropped from the distributor and in the case where at least one of the electronic device or the nurse call slave has dropped from the distributor. The voltage appearing at will be different. Therefore, by detecting the voltage value appearing on the other end side of the first resistor via the voltage detection circuit, not only the nurse call slave unit has been dropped from the distributor, but also an electronic device (for example, a mat sensor) It can also be detected that it has dropped out.

It is a figure which shows the structural example of the nurse call system by 1st Embodiment. It is a figure which shows the structural example of the nurse call system by 2nd Embodiment. It is a figure which shows the structural example of the nurse call system by 3rd Embodiment. It is a figure which shows the structural example of the conventional nurse call system.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example of a nurse call system according to the first embodiment. In the nurse call system according to the present embodiment, as shown in FIG. 1, a distributor 120 is connected to the wall-embedded child device 100, and the distributor 120 connects the hand child device 140 (the nurse call child device of the present invention). And a mat sensor 160 having a nurse call function (corresponding to the electronic apparatus of the present invention) are connected in parallel.

  The wall-embedded portable device 100 includes a power source 200 that supplies a predetermined voltage (voltage value Vcc in the present embodiment), a first resistor 220 (one resistance value R1 in the present embodiment) having one end connected to the power source 200, A voltage detection circuit 260 for detecting a voltage appearing at an end point 240 on the other end side of the first resistor 220 and a connection connector 280 for connecting the distributor 120 to the wall-embedded child device 100 are provided. The connection connector 280 includes a signal terminal 280a connected to the end point 240 and a signal terminal 280b connected to the ground inside the wall-embedded slave unit 100.

  The distributor 120 includes a first connection connector 300 for connecting to the wall-embedded handset 100, a second connection connector 320 for connecting the hand-type handset 140, and a first connection connector for connecting the mat sensor 160. 3 connection connectors 340 are provided. The first connection connector 300 includes a signal terminal 300a for connecting to the signal terminal 280a of the connection connector 280 included in the wall-embedded slave unit 100, and a signal terminal 300b for connecting to the signal terminal 280b of the connection connector 280. ing. The second connection connector 320 includes two signal terminals 320a and 320b. The third connection connector 340 includes three signal terminals 340a, 340b, and 340c.

  The signal terminal 300a of the first connection connector 300 is connected to the signal terminal 340a of the second connection connector 340 by wiring. The signal terminal 300b of the first connection connector 300 is connected to the signal terminal 320b of the second connection connector 320 and the signal terminal 340c of the third connection connector 340 by wiring. The signal terminal 320a of the second connection connector 320 is connected to the signal terminal 340b of the third connection connector 340 by wiring.

  The hand slave unit 140 includes a connection connector 400 for connecting to the distributor 120, a second resistor 420 (resistance value in the present embodiment: R2), and a call button (not shown) of the hand slave unit 140 by the patient. ), The second switch 440 is turned on. The connection connector 400 includes a signal terminal 400a for connecting to the signal terminal 320a of the second connection connector 320 included in the distributor 120, and a signal terminal 400b for connecting to the signal terminal 320b of the second connection connector 320. Yes. The main body of the hand slave unit 140 and the connection connector 400 are connected by a cable of the hand slave unit 140. Note that the resistance value R2 of the second resistor 420 may be the same as or different from the resistance value R1 of the first resistor 220. Further, the resistance value of the second switch 440 is extremely small so as to be negligible compared to the resistance value R2 of the second resistor 420.

  The second resistor 420 and the second switch 440 are connected in parallel between the signal terminal 400a of the connection connector 400 and the ground. The signal terminal 400b of the connection connector 400 is connected to the ground inside the hand-type slave unit 140.

  The mat sensor 160 includes a connection connector 500 for connecting to the distributor 120, and a first switch 520 that is turned on when a weight change is detected by a weight sensor (not shown). The connection connector 500 includes a signal terminal 500a for connecting to the signal terminal 340a of the third connection connector 340 included in the distributor 120, a signal terminal 500b for connecting to the signal terminal 340b of the third connection connector 340, and a third. The signal terminal 500c for connecting with the signal terminal 340c of the connection connector 340 is provided. The mat sensor 160 and the connection connector 500 are connected by a mat sensor 160 cable. Note that the resistance value of the first switch 520 is extremely small as compared with the resistance value R2 of the second resistor 420.

  The first switch 520 is connected in series between the signal terminal 500 a and the signal terminal 500 c of the connection connector 500. Further, the signal terminal 500a and the signal terminal 500b of the connection connector 500 are directly connected. That is, in the wiring connecting from the wall-embedded slave unit 100 to the mat sensor 160 via the distributor 120, the distributor branches off from the wiring connecting the distributor 120 and the mat sensor 160 (first switch 520). The wiring connected to 120 is formed by directly connecting the signal terminal 500a and the signal terminal 500b of the connection connector 500.

  In the configuration as described above, the wall-embedded slave unit 100 detects the voltage appearing at the end point 240 on the other end side of the first resistor 220 by the voltage detection circuit 260, so that the second The on / off state of the first switch 440 and the on / off state of the first switch 520 of the mat sensor 160 can be determined. This will be described below.

  First, when the second switch 440 of the hand-type slave unit 140 and the first switch 520 of the mat sensor 160 are in the OFF state, the distributor 120 and the mat sensor 160 are passed again from the wall-embedded slave unit 100 to the distributor again. A current path that connects from the power source 200 to the ground through the first resistor 220 and the second resistor 420 is formed by the wiring that connects to the hand-shaped slave unit 140 through 120. Specifically, the power source 200, the first resistor 220, the signal terminal 280a, the signal terminals 300a and 340a in the distributor 120, the signal terminals 500a and 500b in the mat sensor 160, the distributor 120 A current path connecting the signal terminals 340b and 320a, the signal terminal 400a in the hand-type slave unit 140, the second resistor 420, and the ground is formed. Therefore, the power supply voltage Vcc is divided by the resistance values R1 and R2 of the first resistor 220 and the second resistor 420 connected in series on the current path at the end point 240 of the wall-embedded child device 100. Voltage value (= Vcc × R2 / (R1 + R2)) is generated.

  In this state, when the second switch 440 is turned on, for example, when the patient presses the call button of the handheld device 140, the end point 240 is short-circuited to the ground via the second switch 440. The voltage of 240 becomes a value close to zero. On the other hand, when the change in weight is detected by the weight sensor and the first switch 520 is turned on, the end point 240 is short-circuited to the ground via the first switch 520, so that the voltage at the end point 240 becomes zero. A close value.

  Thus, the on state of the switches 440 and 520 is detected based on whether or not the voltage at the end point 240 is close to zero. When the ON state of the switches 440 and 520 is detected by the wall-embedded slave unit 100, the corridor lamp (not shown) and the nurse call parent unit (not shown) are called in this order from the wall-embedded slave unit 100. A signal is transmitted and the nurse is informed of the call from the patient.

  Next, consider a case where the hand-type slave unit 140 drops from the distributor 120 (that is, the second connection connector 320 of the distributor 120 and the connection connector 400 of the hand-type slave unit 140 are disconnected). Note that neither the first switch 520 nor the second switch 440 is in an on state. In this case, before the hand-type slave unit 140 is dropped, as described above, a current flows from the power source 200 to the ground through the first resistor 220 and the second resistor 420 (a current path is formed), and the end point 240 In this case, the power supply voltage Vcc is divided by the resistance value R1 of the first resistor 220 and the resistance value R2 of the second resistor 420.

  On the other hand, after the hand-shaped slave unit 140 is dropped, a current path through which current flows from the power source 200 through the first resistor 220 and the second resistor 420 to the ground is not formed, and the tip of the first resistor 220 ( Precisely, the tip of the second connection connector 320 provided in the distributor 120 is an open end. For this reason, the voltage appearing at the end point 240 is not a divided voltage of the power supply voltage Vcc described above. That is, the voltage appearing at the end point 240 is different before and after the hand-type slave unit 140 is dropped, and the voltage after dropping is not a value close to zero when any of the switches 440 and 520 is in the ON state. By monitoring the voltage with the voltage detection circuit 260, it is possible to detect that the hand-type slave unit 140 has dropped from the distributor 120.

  Next, consider a case where the mat sensor 160 is dropped from the distributor 120 (that is, the connection connector 340 of the distributor 120 and the connection connector 500 of the mat sensor 160 are disconnected). Before the mat sensor 160 is dropped, a current flows from the power source 200 to the ground through the first resistor 220 and the second resistor 420 (a current path is formed), and the resistance value of the first resistor 220 is at the end point 240. The power supply voltage Vcc is divided by R1 and the resistance value R2 of the second resistor 420.

  On the other hand, after the mat sensor 160 is removed, a current path through which current flows from the power source 200 to the ground through the first resistor 220 and the second resistor 420 is not formed, and the tip of the first resistor 220 (exactly The tip of the third connection connector 340 included in the distributor 120 is an open end. For this reason, the voltage appearing at the end point 240 is not a divided voltage of the power supply voltage Vcc described above. That is, the voltage appearing at the end point 240 is different before and after the mat sensor 160 is dropped, and the voltage after dropping is not a value close to zero when any of the switches 440 and 520 is in the on state. By monitoring with the voltage detection circuit 260, it is possible to detect that the mat sensor 160 has dropped from the distributor 120.

  As described above in detail, in the first embodiment, in the configuration in which the hand-shaped child device 140 and the mat sensor 160 are connected in parallel from the distributor 120, the wiring directly connected from the distributor 120 to the hand-shaped child device 140 is used. Instead, a wiring connecting the distributor 120 to the hand-type slave unit 140 via the mat sensor 160 was formed. For this reason, when neither the hand type slave unit 140 nor the mat sensor 160 has dropped from the distributor 120, and when at least one of the hand type slave unit 140 or the mat sensor 160 has dropped from the distributor 120, the end points The voltage appearing at 240 can be different. Therefore, by monitoring the voltage value appearing at the end point 240 by the voltage detection circuit 260, it is possible to detect not only that the hand-type slave unit 140 has dropped from the distributor 120 but also that the mat sensor 160 has dropped. In the first embodiment, the voltage value appearing at the end point 240 when the hand-type slave unit 140 is dropped is the same as the voltage value appearing at the end point 240 when the mat sensor 160 is dropped. I can't tell if I did it.

  Next, a second embodiment of the present invention will be described. FIG. 2 is a diagram illustrating a configuration example of a nurse call system according to the second embodiment. In FIG. 2, components having the same functions as those shown in FIG. 1 are given the same reference numerals, and redundant descriptions are omitted.

  In the second embodiment, the distributor 120 ′ further includes a third resistor 600 (resistance value: R3 in the present embodiment). The third resistor 600 is a wiring connecting the hand-type slave unit 140 and the mat sensor 160 (that is, between the signal terminal 320a of the second connection connector 320 and the signal terminal 340b of the third connection connector 340). One end is connected to the wiring) and the other end is connected to the ground. That is, the third resistor 600 is connected in parallel with the second resistor 420. The resistance value R3 of the third resistor 600 may be the same as or different from the resistance value R1 of the first resistor 220. Further, the resistance value R3 of the third resistor 600 may be the same as or different from the resistance value R2 of the second resistor 420.

  Consider the case where the hand-type slave unit 140 is dropped from the distributor 120 'in the above-described configuration. Before the hand-held device 140 is dropped, a current path is formed so that a current flows from the power source 200 to the ground through the first resistor 220, the second resistor 420, and the third resistor 600. Thereby, the end point 240 is divided by the resistance value R1 of the first resistor 220 and the combined resistance value of the resistance value R2 of the second resistor 420 and the resistance value R3 of the third resistor 600. Has occurred.

  On the other hand, after the hand-held device 140 is dropped, a current path is formed so that a current flows from the power source 200 through the first resistor 220 and the third resistor 600 to the ground. As a result, at the end point 240, the power supply voltage Vcc is divided by the resistance value R1 of the first resistor 220 and the resistance value R3 of the third resistor 600. That is, the voltage appearing at the end point 240 is different before and after the hand-type slave unit 140 is dropped, and the voltage after dropping is not a value close to zero when any of the switches 440 and 520 is in the ON state. By monitoring the voltage with the voltage detection circuit 260, it is possible to detect that the hand-type slave unit 140 has dropped from the distributor 120 ′.

  Next, consider a case where the mat sensor 160 is dropped from the distributor 120 '. Before the mat sensor 160 is dropped, the state is the same as before the hand-shaped slave unit 140 is dropped. On the other hand, after the mat sensor 160 is removed, a current path that flows from the power source 200 through the first resistor 220, the second resistor 420, and the third resistor 600 to the ground is not formed. The tip is the open end. For this reason, the voltage appearing at the end point 240 differs before and after the mat sensor 160 is removed. In addition, the voltage after dropping is not a value close to zero when any of the switches 440 and 520 is on, and is not a divided voltage when the hand-type slave unit 140 is dropped. By monitoring the voltage by the voltage detection circuit 260, it is possible to detect that the mat sensor 160 is dropped from the distributor 120 ′ (not the hand-type slave unit 140).

  As described above in detail, according to the second embodiment, the third resistor 600 is provided in the distributor 120 ′, so that when the hand-type slave unit 140 is dropped from the distributor 120 ′, the end point 240 is reached. The voltage that appears can be different from the voltage that appears at the end point 240 when the mat sensor 160 is removed from the distributor 120 ′. In addition, the voltage appearing at the end point 240 after any one of the hand-held device 140 and the mat sensor 160 is not a value close to zero when any of the switches 440 and 520 is in the ON state. Therefore, by monitoring the voltage at the end point 240 by the voltage detection circuit 260, it is possible to identify that the hand-type slave unit 140 has dropped from the distributor 120 ′ and that the mat sensor 160 has dropped from the distributor 120 ′. Can be detected.

  Next, a third embodiment of the present invention will be described. FIG. 3 is a diagram illustrating a configuration example of a nurse call system according to the third embodiment. In FIG. 3, components having the same functions as those shown in FIG. 1 are given the same reference numerals, and redundant descriptions are omitted.

  In the third embodiment, the distributor 120 ″ further includes third switches 700 and 720. The third switches 700 and 720 enable the wiring connected to the hand-type slave unit 140 via the mat sensor 160 or disable the wiring connected to the hand-type slave unit 140 via the mat sensor 160. Whether to form wiring directly connected to the machine 140 is switched. The switching of the third switches 700 and 720 is manually performed by the user.

  The third switches 700 and 720 are switched on and off in conjunction with each other. That is, as shown in FIG. 3A, when one switch 700 is in an off state, the other switch 720 is in an on state. In this case, the wiring configuration in the distributor 120 ″ is the same as the wiring configuration in the distributor 120 of FIG. On the other hand, as shown in FIG. 3B, when one switch 700 is on, the other switch 720 is off.

  In the state of FIG. 3B, a current flows from the power source 200 to the ground through the first resistor 220 and the second resistor 420 regardless of whether the first switch 520 is in the off state or the on state. Flowing. That is, the voltage at the end point 240 has the same value regardless of whether the first switch 520 is on or off. In other words, even if the first switch 520 of the mat sensor 160 is turned on, the voltage value at the end point 240 is not affected.

  As described in detail above, according to the third embodiment, the third switch 700, 720 is provided in the distributor 120 '', so that, for example, when the nurse performs care for the patient, the mat sensor It is not necessary to remove the connection connector 500 of 160, and the mat sensor 160 can be electrically disconnected from the distributor 120 ″ by a simple operation of operating the third switches 700 and 720.

  In each of the embodiments described above, an example in which a current path is distributed from the wall-embedded slave unit 100 to the hand-type slave unit 140 and the mat sensor 160 via the distributor 120 (120 ′, 120 ″) will be described. However, the present invention is not limited to this. For example, instead of the mat sensor 160, another medical electronic device having a nurse call function such as a ventilator or a biological monitor for monitoring a patient's electrocardiogram may be connected. In this case, as in the case where the mat sensor 160 is connected, by monitoring the voltage at the end point 240 by the voltage detection circuit 260, the hand-type slave unit 140 is dropped from the distributor 120 (120 ′, 120 ″). In addition to this, it is possible to detect that the medical electronic device has dropped out.

  Further, the second embodiment and the third embodiment may be combined. That is, the distributor 120 (120 ′, 120 ″) may include both the third resistor 600 and the third switches 700 and 720. In this case, by monitoring the voltage at the end point 240 by the voltage detection circuit 260, the hand-type slave unit 140 has dropped from the distributor 120 (120 ′, 120 ″) and the distributor 120 (120 ′, 120). )), The mat sensor 160 can be identified and detected, and the mat sensor 160 can be electrically connected from the distributor 120 (120 ′, 120 ″) simply by a switch operation at a desired timing. Can be removed.

  Further, in each of the embodiments described above, the wiring connected to the mat sensor 160 from the wall-embedded slave device 100 via the distributor 120 (120 ′, 120 ″) is connected to the mat sensor 160. Although an example of branching in the main body of the mat sensor 160 has been described, it may be branched in the cable of the mat sensor 160.

  In addition, each of the embodiments described above is merely an example of a specific example for carrying out the present invention, and the technical scope of the present invention should not be construed as being limited thereto. is there. In other words, the present invention can be implemented in various forms without departing from the spirit or main features thereof.

100 Wall Embedded Type Slave Unit 120, 120 ′, 120 ″ Distributor 140 Hand Type Slave Unit 160 Mat Sensor 200 Power Supply 220 First Resistor 260 Voltage Detection Circuit 420 Second Resistor 440 Second Switch 520 First Switch 600 third resistor 700 third switch 720 third switch

Claims (3)

In a nurse call system in which a distributor is connected to a wall-embedded child device, and a nurse call child device and an electronic device having a nurse call function are connected in parallel from the distributor.
The wall-embedded slave unit is
A power supply for supplying a predetermined voltage;
A first resistor having one end connected to the power source;
A voltage detection circuit for detecting a voltage appearing on the other end side of the first resistor,
The electronic device is
A first switch that switches between conduction and non-conduction according to whether the nurse call function is activated, and the first switch is connected from the wall-embedded slave to the electronic device via the distributor; The wiring is connected in series with the first resistor between the other end of the first resistor and the ground,
Branching from the wiring connecting the distributor and the electronic device in the wiring connected to the electronic device from the wall-embedded child device via the distributor, and further passing through the distributor to the nurse call child device A second resistor connected in series with the first resistor between the other end of the first resistor and the ground by a connecting wire;
A second switch connected in parallel to the second resistor between the other end side of the first resistor and the ground, and switches between conduction and non-conduction according to the presence or absence of a nurse call call operation; Nurse call system characterized by having. The nurse call system according to claim 1,
The distributor includes a third resistor having one end connected to the wiring connecting the electronic device and the nurse call slave and the other end connected to the ground. system. The nurse call system according to claim 1 or 2,
The distributor enables the wiring connected to the nurse call slave unit via the electronic device or invalidates the wiring connected to the nurse call slave device via the electronic device to the nurse call slave unit. A nurse call system, further comprising a third switch for switching whether to form a directly connected wiring.

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