JPS62261334A - Patient monitor apparatus - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a patient monitoring device that collectively monitors biological signals such as body temperature, blood pressure, and pulse of a large number of patients at a nursing station.

[Conventional technology]

BACKGROUND ART Various patient monitoring devices have been proposed in hospitals and the like for collectively monitoring the biological signals of a large number of patients at a nurse station. These conventional patient monitoring devices are equipped with individual transmission lines to obtain individual detection signals from the central device and slave detectors installed next to the patient's bed, or are equipped with fewer transmission lines due to time-sharing, etc. Detection signals are obtained from the detectors of each child device.

[Problem that the invention seeks to solve]

However, in the case of the conventional patient monitoring device using individual lines as described above, individual lines must be installed between each patient's bed and the nurse's station. As a result, the number of lines increases,
Therefore, the installation work becomes very difficult and the equipment costs are high. Similarly, in patient monitoring devices that use conventional time-sharing to reduce the number of lines, accurate detection from all slave units is difficult due to the constraint of collecting detection signals from each slave unit via the same line. There was a problem that it took a long time to obtain a signal.

[Means to solve the problem]

In the patient monitoring device according to the present invention, a plurality of child devices are connected in parallel to a line extending from the central device, and the central device has a
A calling means that sequentially sends the address signal of each slave device to call each slave device, and a storage means for storing the detection signal obtained from the detector are provided, and each slave device is provided with a calling means that sequentially sends an address signal of each slave device to call each slave device, and a storage means that stores the detection signal obtained from the detector. address match detection means for outputting an address match signal when there is a calling address that matches the address assigned to itself in the signal; and a detection start display means driven by the address match signal and a control signal from the central device. , a detection completion signal generation means for generating a signal notifying the completion of detection, and a detection signal transmission means for transmitting the detection signal to the central device are provided, and after the central device has driven the detection start display means of the slave device. The above-mentioned problem is solved by activating the detection signal sending means to collect the detection signals only when a detection completion signal is received from the child device, and storing the detection signals in the storage means.

[Effect]

Since the patient monitoring device according to the present invention is equipped with the above-mentioned means, when collecting detection signals from the detectors of the slave devices, the central device activates the detection start display means of the slave devices to notify the patient. The start of detection is notified, and the patient then sets the detector. When the detection is completed, the detection completion signal generating means is activated to notify the central device of the completion of the detection.

The central device collects detection signals from its slave devices only after receiving this detection completion signal.

〔Example〕

FIG. 1 is a schematic configuration diagram of one embodiment of the patient monitoring device according to the present invention, which includes a central device (C) installed at the nurse's station, and slave devices (Ts) installed near each patient bed. ~ expressions are connected by transmission lines (L).The central unit (C) includes a central processing unit (CPU) that performs arithmetic processing according to various instructions, a transmission circuit (TC), a memory ( M) and a console (CB) are provided via an interface circuit (IF).A transmission circuit (TC) performs signal exchange between the central processing unit (CPU) and the transmission line (t). The memory (M) is provided with a detection signal buffer that stores at least a control program for the entire patient monitoring device, a detection flag and a detection signal, which will be described later. A detection start switch (SS) that generates a control signal to notify the start of detection, a detection completion indicator (CD) to notify that detection is complete, and a detection signal that is not completed within a predetermined period. A warning display (AD) that indicates the existence of slave devices that cannot be collected, and a keyboard (KB) that allows you to select slave devices are provided. A counter is also provided. Each slave unit (TI-n) is provided with a transmission circuit (TU), a signal processing circuit (SP), etc. Transmission circuit (TU) Fi, signal processing circuit (SP), etc.
) and the transmission line (t). The signal processing circuit (sp) is shown in the second section, which shows the configuration of the child device in more detail.
As is clear from the schematic configuration diagram in the figure, at least an address setter (As) that sets its own address, an address signal sent from the central unit (C) via a transmission circuit (TU), and this address setting an address match detector (As) that generates an address match signal when a match is detected by comparing the address signals obtained from the address match detector (As);
AC) and the command that is activated in response to this address match signal and is sent from the central unit (C) via the transmission circuit (TU) into control signals, etc., and generates the respective signals. (DC), a display controller (CH) that lights up a detection start indicator (SD) based on a signal from the command discriminator (DC), and a detection completion switch that also lights up a detection start indicator (SD) based on a signal from the command discriminator (DC). A signal converter (SC) that converts the signal from the CS (CS) into a signal sent to the transmission circuit (TU), and a command discriminator (DC)
It is composed of an A/D converter (ADC) that converts the analog signal from the detector (D) into a digital signal and sends it to the transmission circuit (TU). In this embodiment, a thermometer is used as the detector (D). Furthermore, a flip-flop circuit (FF) is provided between the display controller (CH) and the detection start indicator (SD) in order to display continuously.

The operation of the patient monitoring device according to the present invention configured as described above will be explained based on the flowcharts of FIGS. 3 to 6.

Once this patient monitoring device is put into operation, the central device (C)
performs processing according to the main routine shown in FIG. That is, the detection signal buffer, detection flag, and counter are cleared by the initialization routine. Next, set the address n of the child device to be called to 11#. This results in
The central device (C) sends this address signal 111 and a subsequent command signal for collecting the detection completion signal of the child device to the transmission line <1> via the transmission circuit (TC). Each slave (T
t-n) takes in these signals via the transmission circuit and compares them with its own address set in the address setter (As) in the address-number configuration circuit (AC) to determine if they match. If so, generate an address match signal.

Of course, the address that generates the match signal at this time is address 11.
There is only an address coincidence detector (AC) of one child device (Tt). The command classification device (DC) receives this address matching signal, classifies the command to collect the detection completion signal, and activates the signal converter (SC). At this time, each child device (T1 to n) Since it has not received a command to start detection from the central device (C), it naturally does not send a detection completion signal to the central device (C). In this way, the central device (C) sequentially sends out address signals and command signals from the slave unit at address III to the slave unit at final address 1Nl during normal operation.

Therefore, K, who performs the detection, turns on the detection start switch (SS) in the central unit f (C). In this embodiment, the signal indicating the start of detection is maintained for at least a period longer than the period required for the main routine to complete one cycle, and then disappears. Then, the central device (C) sets the detection Z lag by inputting this detection start switch signal, and then sets the slave device (T) at address 11'.
1) to the slave device (Tn) at the final address, the address signal of the slave device and subsequently the command signal for turning on the display controller (CH) are sent to the transmission line (t).

Each child device (T) that receives the call triggers a flip-flop circuit (FF) to light up a detection start indicator (SD). As a result, if each patient does not perform detection, it can be determined that detection has been completed after the required predetermined time has elapsed, and the patient can use the detection completion switch (CS).
), the 8 central unit f(C) inputs all child units (Tl-n
) After sending a command signal to turn on the display control i% (CH), the mode is set to activate the signal converter (SC) of each child device (T1 to n) to collect the detection completion signal. Since the detection completion switch (
When aS) is turned on, it can be immediately known that the child device has completed detection. Central unit all (C) is
For the slave device (T) that has received this detection completion signal, check whether a detection signal has already been collected from the slave device (T),
If the data has not yet been collected, the address signal of the child device (T) and the command signal for operating the A/D converter (ADC) are sent to the transmission line (t). The slave device (T) that receives this command signal activates the A/D converter (ADC) to convert the analog detection signal obtained from the detector (D) into a digital signal, and then transmits the signal via the transmission circuit (TU). and send it to the transmission line <1). The central device (C) collects this detection signal and stores it in a detection signal buffer assigned to this child device. In this way, when the central device (C) receives the detection completion signal from each child device (T+ -n), it collects the detection signal from the child device and stores it in the corresponding detection signal buffer. It is not possible to carry out this work indefinitely until a detection signal is obtained from the single-metal device.

If a detection completion signal is not sent from a slave unit even after the period required for normal detection has elapsed after the start of detection, the patient monitored by that slave unit will switch to the detection completion switch (CS). It is reasonable to interpret this as a situation in which it is impossible to operate the system. Therefore, in order to detect the occurrence of such a situation, this embodiment provides a counter that is incremented each time the main routine is completed after the detection start switch signal is generated, and the count value of this counter reaches a predetermined value. If there is a slave device to which a detection completion signal is not sent even after the detection completion signal has been reached, a warning is displayed as an abnormal situation. That is, the central unit f(C) checks whether the detection flag is set in its routine, and if it is set, all slave units (TI-n
) is detected. If the collection has been completed, the detection flag is cleared and a detection completion display is displayed to notify the supervisor that the detection has been completed. However, if the detection signal collection has not yet been completed, the counter is incremented by a predetermined value, and it is checked whether the counted value of the counter has reached the predetermined value. If the counted value has reached a predetermined value, a warning is displayed indicating that an abnormal situation has occurred.

The above is a complete flow from the start of detection to the completion of detection. Once completion is displayed, the supervisor receives the detection signals obtained from each patient stored in the detection signal buffer. , and output it to an external output device such as a printer for use, but if a warning is displayed, go to the patient who has a slave device that is not generating a detection completion signal and find out why the signal is not being generated. It is necessary to investigate.

In the above embodiment, a switch means based on the patient's own operation is used as the detection completion signal generating means, but with this, measurement errors are likely to occur due to operation errors of each patient. Therefore, it is also possible to use means for automatically generating a detection completion signal from the variation form of the detection signal as shown in FIG. That is, in this embodiment, the thermometer uses a thermistor (TH) as a detector, and the detection signal obtained from the detection bridge including the thermistor (TH) is transmitted through an operational amplifier (OP
) and then output as an analog detection signal from the output terminal (OUT). This operational amplifier (OP
) is input to a first comparator (CR) which generates an output when the voltage is higher than the set voltage, and a second comparator (CR) which outputs an output when the detection signal changes gradually through a differentiating circuit. is input to the comparator (CPz). Then, the logical product of the outputs of the first and second comparators (CPI, 2) is used as a detection completion signal. With this configuration, for example, the output point of the first comparator (CPr) is set when the detector detects a temperature of 36° C. or higher, and the second
If the output point of the comparator (CF2) is set when the temperature change becomes 1/10oC or less in 10 seconds, body temperature can be measured accurately and each hand device (T!~n) can be detected. The error will be eliminated. Furthermore, even if the patient uses such a detection completion signal generation means, the detection completion signal resets the flip-flop circuit (FF), so the patient cannot know the completion of detection by turning off the detection start indicator (SD). can.

In the embodiment described above, the power supply to the detector (D) is always provided within the child device, but in this case, the power supply is wasted and detection errors are likely to occur. Therefore, the 8th
If a power supply means as shown in the figure is provided in the child device, this problem will disappear.

That is, in the slave device configuration as shown in Figure 2, the A/D converter (AD) is triggered by the output of the display controller (CH).
The output from the command discriminator (DC) that operates C) is reset via the delay circuit (DL) and sent to the reset terminal (FF2). The power supply to the detector (D) is controlled by the output. With this configuration, the slave unit (T) will immediately display the detection start indicator (SD) upon receiving the command to start detection.
At the same time, power is supplied to the detector (D).

When the extraction is completed, the CPU receives a command to collect detection signals from the central unit ff (C), activates the A/D converter (ADC), sends the detection signal to the central unit t (C), and sends the detection signal to the delay circuit. After the transmission of the detection signal is completed by the action of (DL), the power supply to the detector (D) is stopped. In this way, the power supply to the detector (D) can be suppressed to the necessary minimum.

In the above embodiment, the detection start indicator (SD) is controlled to blink by the output of the flip-flop circuit (FF), but it is turned on by direct control from the central device (C) to receive the detection signal. After that, the light may be turned off by direct control.

In the above embodiment, the transmission speed is improved by collecting only the detection completion signal during normal signal collection, but if the detection signal is also collected during normal times, the transmission speed will not be improved, but processing will be performed after receiving the completion signal. This reduces the burden on the central device.

〔Effect of the invention〕

As described above, the patient monitoring device according to the present invention has a plurality of child devices connected in parallel to a line extending from the central device,
The central device is provided with a calling means for calling each slave device by sending out the address signal of each slave device 111 times, and a storage means for storing the detection signal obtained from the detector. , address-number configuration means for outputting an address match signal when there is a calling address that matches -1 with the address given to itself in the call signal from the central device, and control from the address match signal and the central device. A detection start display means driven by a signal, a detection completion signal generation means for generating a signal notifying completion of detection, and a detection signal sending means for sending the detection signal to the central device are provided, and the central device/device is configured to: Only when a detection completion signal is received from the slave unit after driving the detection start display unit of the slave unit, the detection signal sending unit is activated to collect the detection signal, and the detection signal is stored in the storage unit. I made it. Because of this, it is only necessary to provide a common line between the central device and each child device, and the entire equipment becomes simple and inexpensive. In addition, although the detection signals are collected from each slave unit through a common line, the detection signals are not collected until the detection completion signal is received, so there is no wasted transmission, and this reduces the overall transmission speed of the device. Since the detection signal is collected only after the detection start signal is sent and when the detection completion signal is received, there is no need to collect a wrong detection signal, and the reliability is high.

Next, as the detection completion signal generation means, the change form of the time characteristic of the detection signal is compared with a predetermined change form to generate a signal that announces the completion of detection, so the detection signal has even less detection error. can be obtained from each detector.

Furthermore, since the slave unit is equipped with a power supply means for the detector, which is controlled by control signals from the central device, the power supply to the detector can be kept to the minimum necessary, and the power capacity of the entire device is can be made smaller.

[Brief explanation of drawings]

FIG. 1 is a schematic configuration diagram of one embodiment of the patient monitoring device according to the present invention, FIG. 2 is a schematic configuration diagram showing details of the child device (T) in FIG. 1, and FIGS. A flowchart used to explain the patient monitoring device according to the invention, FIG. 7 is a circuit diagram of a main part of the detection completion signal generating means used in the patient monitoring device according to the invention, and FIG. 8 is a slave device used in the patient monitoring device according to the invention. FIG. 2 is a schematic configuration diagram of another embodiment of the present invention, in which the same parts are indicated by the same reference numerals throughout each figure. D...Detector, C...Central device %T1~n...Slave device, CPU...Central processing unit, M...Memory, CB
...Operation console, SP...Signal processing circuit, AS...Address setting device, AC...Address-number configuration device, DC...
...Command identifier, CH...Display controller, SC...
・Signal converter, ADC...A/D converter, SS・
...Detection start switch, SD...Detection start indicator, C
D...Detection completion indicator, AD...Warning indicator Patent applicant Nitta/Co., Ltd. Figure 3 Figure 4 Figure 6 Figure 7 Figure 8 Procedural amendment (voluntary) March 1988 Ta Day

Claims (4)

[Claims] (1) In a patient monitoring device that has a detector for detecting biological signals such as the patient's body temperature, blood pressure, and pulse rate, and consists of multiple slave units connected in parallel to a line extending from the central unit, is provided with calling means for sequentially sending the address signal of each slave device to call each slave device, and storage means for storing the detection signal obtained from the detector, and each slave device is provided with the above-mentioned address match detection means for outputting an address match signal when there is a call address that matches the address assigned to itself in the call signal from the central unit; a detection start display means for generating a detection start display means, a detection completion signal generation means for generating a signal notifying the completion of detection, and a detection signal transmission means for transmitting the detection signal to the central device; Only when a detection completion signal is received from the child device after driving the display means, the detection signal sending means is activated to collect the detection signal, and the detection signal is stored in the storage means. patient monitoring equipment. (2) The detection completion signal generation means is a means for generating a signal that notifies the completion of detection by comparing the change form of the time characteristic of the detection signal with a predetermined change form. Patient monitoring equipment. (3) In a patient monitoring device that has a detector for detecting biological signals such as the patient's body temperature, blood pressure, and pulse, and consists of a plurality of slave devices connected in parallel to a line extending from the central device, is provided with calling means for sequentially sending the address signal of each slave device to call each slave device, and storage means for storing the detection signal obtained from the detector, and each slave device is provided with the above-mentioned address match detection means for outputting an address match signal when there is a call address that matches the address assigned to itself in the call signal from the central unit; a detection start display means and a detector power supply means, a detection completion signal generation means for generating a signal notifying the completion of detection, and a detection signal sending means for sending the detection signal to the central device; , only when a detection completion signal is received from the slave device after driving the detection start display means and the detector power supply means of the slave device, the detection signal sending means is activated to collect the detection signal, and the detection signal is collected. A patient monitoring device characterized in that the information is stored in a storage means. (4) The detection completion signal generation means is a means for generating a signal that notifies the completion of detection by comparing the change form of the time characteristic of the detection signal with a predetermined change form. Patient monitoring equipment.