KR20180061613A - Lighting for hospital - Google Patents

Abstract

The present invention relates to a lighting system for a hospital installed in a hospital. The lighting control system for a hospital includes: an LED module including a plurality of LEDs; a rectifying part rectifying AC power for common use inputted from the outside into predetermined DC power to deliver the power to the LED module; a sensor part generating a sensing signal by sensing at least one among motion, temperature, and respiration; a patient monitoring device detecting a bio signal including at least one among an electrocardiogram signal, a blood oxygen saturation signal, and a blood pressure signal; and a control part receiving the sensing signal and bio signal from the sensor part and the patient monitoring device, thereby generating and delivering a predetermined PWM control signal to the rectifying part. The rectifying part is able to control the on/off and dimming of the LED module in accordance with the control signal.

Description

{LIGHTING FOR HOSPITAL}

The present invention relates to a hospital lighting system installed in a hospital room.

In recent years, light emitting diodes (LEDs) capable of realizing bright illumination due to the short lifetime of fluorescent lamps and high power consumption have been widely used, and their use range has been expanded to various types of lighting devices. Attempts are being made actively.

LEDs emit light to emit light when current is applied. Light emitting diode lighting devices can be driven at a low voltage and have a longer lifetime, lower power consumption, faster response speed and stronger impact resistance than other lighting devices, .

However, such a LED is disadvantageous in that strong light is irradiated at once and stress due to glare occurs. Particularly, such glare is a psychological stress factor for the patient, and there is a disadvantage that the eyes are not instantly visible to the doctor who is in the process of surgery.

Korean Patent Laid-Open Publication No. 1020130101180 (published Sep. 13, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a dimming control method for illuminating an LED lighting installed in a hospital.

It is another object of the present invention to enable the LED lighting to be automatically turned on by sensing the motion of the human body.

It is another object of the present invention to control the LED illumination so as to detect the emergency situation of the patient and inform the medical staff.

The present invention is a hospital lighting system for solving the above problems. The lighting system for a hospital of the present invention includes an LED module including a plurality of LEDs, a rectifying unit for rectifying a commercial AC power input from the outside, rectifying the rectified AC power to a predetermined DC power source and transmitting the rectified AC power to the LED module, A patient monitoring device for detecting a biological signal including at least one of an electrocardiogram signal, a blood oxygen concentration signal, and a blood pressure signal of a patient, a sensor unit for sensing one of the sensor signal and the sensing signal, And a control unit for receiving the biological signal and generating a predetermined PWM control signal based on the generated PWM control signal and transmitting the generated PWM control signal to the rectifying unit.

Also, the rectifying unit can dim the LED module according to the control signal.

The control unit may include an input unit for receiving the sensing signal and the bio-signal, an analyzer for analyzing the sensing signal and the biological signal provided from the input unit and determining a dimming pattern based on the sensing signal and the biological signal, And generate a PWM control signal based on the received control signal.

The controller may generate a first PWM control signal when at least one of a sound and a motion is sensed by the sensor unit, transmit the first PWM control signal to the rectifying unit, can do.

The controller may include a sensor for sensing at least one of body temperature and respiration of the patient, and when the at least one of the preset body temperature and respiration is out of a preset range, the controller may output a second PWM control signal And transmits the second PWM control signal to the rectifying unit to dim the LED module.

The controller receives a bio-signal from the patient monitoring apparatus, generates a third PWM control signal when the bio-signal is out of a preset range, and transmits the control signal to the rectifying unit, Can be dimmed on and off.

When the dimming control is performed on the LED module according to the first PWM control signal, the control unit sets the control level to the first step and controls the LED module to dimming on the basis of the second PWM control signal , The control level can be set to the second step and the control level can be set to the third step in the case of dimming-on-controlling the LED module according to the third PWM control signal.

The illumination system for a hospital according to another embodiment of the present invention includes a first LED module emitting a first wavelength light and including a plurality of LEDs, a second LED module emitting a second wavelength light and including a plurality of LEDs, An LED unit including a third LED module including a plurality of LEDs emitting light of a wavelength and a commercial AC power source input from the outside by rectifying the AC power source to a predetermined DC power source and supplying the rectified AC power to at least one of the first LED module and the third LED module A sensor unit for sensing at least one of a rectifying part for transmitting and a surrounding sound, a motion of a person, a body temperature of a patient, and a respiration of a patient and generating a sensing signal, and a sensor unit for sensing at least one of an ECG signal, A patient monitoring apparatus for outputting a living body signal, a receiving unit for receiving the sensing signal or the living body signal, and selecting either the first LED module or the third LED module And a control unit for generating a control signal for controlling the illumination pattern of the selected LED module and transmitting the control signal to the rectifying unit.

In addition, the rectifying part may provide a direct current power to drive one selected one of the first to third LED modules in the illumination pattern according to the control signal.

The controller may generate a first control signal for dimming the first LED module when at least one of ambient noise and human motion is sensed by the sensor unit and output the first control signal to the rectifying unit So that the first LED module is dimmed on.

The controller may generate a second control signal to turn on the second LED module according to the first illumination pattern when the body temperature and respiration of the patient sensed by the sensor unit exceed a preset range, And generates a third control signal for turning on the third LED module according to a second illumination pattern when the bio-signal is out of a predetermined range by controlling the second LED module to be turned on, And transmits the third control signal to the rectifier to control the third LED module to be turned on.

The present invention is advantageous in that the LED lighting module installed in the hospital is controlled to dimming on, thereby preventing glare of the patient and the medical staff.

In addition, the present invention detects the motion of a human body and controls the LED lighting module to be automatically turned on so that the patient can turn on his / her own light or turn on the light without the visitor pressing the light switch, .

In addition, the present invention has an advantage of detecting a biological signal of a patient, detecting a dangerous condition of the patient based on the detected biological signal, and informing medical staff of an emergency situation.

FIG. 1 illustrates a lighting system for a hospital according to an embodiment of the present invention.
2 shows a control unit according to an embodiment of the present invention.
3 illustrates a first PWM control signal according to an embodiment of the present invention.
4 illustrates a second PWM control signal according to an embodiment of the present invention.
5 illustrates a third PWM control signal according to an embodiment of the present invention.
6 illustrates a lighting system for a hospital according to another embodiment of the present invention.
7 shows an LED unit according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is susceptible to various modifications and can be made into various embodiments, and specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, number, step, operation, element, component, or combination thereof described in the specification, But do not preclude the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

The present invention relates to a hospital lighting system installed in a hospital.

Illumination used in hospitals should be given to patients, medical staff and visitors to meet different needs of the patient, but also to give priority to patient lighting.

Patients should not be glare when suddenly exposed to strong light, and should light up when the patient is unable to move himself or should the light illuminate automatically when the patient is at risk.

For medical staff, it is necessary to secure the necessary illumination, but also to prevent sudden exposure to strong illumination. Also, the visitor should touch the light switch to prevent the disease from spreading.

When a sudden strong light is irradiated in a dark place, it takes a long time for the retina to acclimatize, resulting in a phenomenon in which the eye can not be seen instantaneously. Such glare is a psychological stress factor for the patient, and the medical staff is a great risk for medical treatment / surgery if such glare occurs during medical treatment, especially during surgery.

The present invention is characterized by a dimming on control which causes the light emitting LED module 40 to gradually brighten when it is turned on to solve this problem.

The lighting system 100 for a hospital according to the present invention may include an LED module 40, a rectification unit 10, a sensor unit 20, and a control unit 30.

The LED module 40 of the present invention includes a plurality of LEDs. Here, the LED and LED module 40 have already been commercialized and widely known, and a detailed description thereof will be omitted.

The rectifying part (10) of the present invention rectifies the used AC power inputted from the outside to a predetermined DC power. The rectified power is transmitted to the LED module 40 side.

The sensor unit 20 of the present invention may sense at least one of ambient sound, human motion, body temperature, and breathing to generate a sensing signal. The generated sensing signal is transmitted to the controller 30. Preferably, the sensor unit 20 and the control unit 30 can transmit and receive a sensing signal using wireless communication.

The patient monitoring apparatus 50 of the present invention can detect a biological signal including at least one of an electrocardiogram signal, a blood oxygen concentration signal, and a blood pressure signal of a patient. Preferably, the patient monitoring device 50 and the control unit 30 can exchange biometric signals using wireless communication.

The control unit 30 may include an input unit 31, an analyzing unit 32, and a control signal generating unit 33.

The input unit 31 of the present invention receives the sensing signal from the sensor unit 20 and the bioelectric signal from the patient monitoring unit and provides the sensing signal to the analyzer 32.

 The analysis unit 32 of the present invention analyzes a sensing signal and a biological signal provided from the input unit 31 and determines a dimming pattern based on the analysis result.

The control signal generator 33 of the present invention receives the dimming pattern from the analyzer 32, generates a PWM control signal based on the dimming pattern, and transmits the PWM control signal to the rectifier.

The rectifying unit 10 of the present invention can dim the LED module 40 to turn on the LED module 40 according to the transmitted PWM control signal and brighten the LED module 40 according to a preset step.

The sensor unit 20 includes a sensor module that senses sound and motion together. The control unit 30 generates a first PWM control signal when sound or motion is sensed by the sensor module, To the rectifying part (10). The rectifying unit 10 can dim the LED module 40 according to the first PWM control signal. Preferably, the first PMS pulse width is 200 to 210 ms and may be the control level of the first stage. Here, the control level refers to a step that is taken until the LED module 40 starts at 0% and becomes 100% bright. For example, if the control level is three levels, the LED module 40 may be totally lighted up through three steps.

Thus, by detecting the motion of the medical staff, the visitor, and the patient, the illumination is automatically turned on even when the medical staff does not turn on the illumination in an emergency, so that appropriate medical care is possible. Visitors can prevent infection by pathogens by pressing a light switch. In addition, a patient who can not properly move a certain part of the body (e.g., a leg) can have a merit of turning on the light by taking simple motion.

In addition, the sensor unit 20 may include a sensor for sensing at least one of a body temperature and respiration of the patient. Preferably, the sensor unit 20 can sense the body temperature of the patient through a radar sensor using the Doppler effect. Also, the sensor unit 20 can sense the breath of the patient through a sensor that detects the concentration of carbon dioxide. The body temperature and / or respiration signal of the patient sensed by the sensor unit 20 may be transmitted to the controller 30. The control unit 30 generates a second PWM control signal when the body temperature and / or respiration signal of the delivered patient is out of a preset range, and transmits the second PWM control signal to the rectifying unit 10, The control unit 40 can control the dimming on. Preferably, the second PMS pulse width is 150-200 ms, and may be a total of four levels of control.

In addition, the control unit 30 receives the bio-signal detected from the patient monitoring device 50, generates a third PWM control signal when the bio-signal is out of a predetermined range, To the rectifier (10) to dim the LED module (40). Preferably, the third PMS pulse width is 120 to 200ms, which may be a total of five levels of control. In this case, the control unit may generate a control signal to transmit the danger signal to the rectifying unit so that the LED module 40 is repeatedly turned on and off for a predetermined period of time.

Thus, the present invention can detect a dangerous situation of a patient and inform the medical staff of the dangerous situation. In addition, when an emergency occurs, even if a medical staff does not turn on the light, the illumination is automatically turned on and the appropriate medical treatment can be performed.

In the present invention, the time when the LED module 40 is fully turned on may be 800 to 1200 ms. For example, when the sensor unit 20 senses motion, the LED module 40 is completely turned on through three levels of control levels of 0 to 200 ms, 300 to 500 ms, and 600 to 800 ms according to the first PWM control signal . If the brightness when the LED module 40 is fully turned on is 100%, the brightness when the LED module 40 is turned on for 0 to 200 ms is 30%, and the brightness of the LED module 40 is 200% When turned on, the brightness can be controlled to be 65%.

In addition, according to another embodiment of the present invention, the risk of a patient can be detected through the illumination color, and the lighting can be controlled according to the patient's situation so that the medical staff can know quickly.

The illumination system for a hospital according to another embodiment of the present invention may include an LED unit 60, a rectification unit 10, a sensor unit 20, a patient monitoring device 50, and a control unit 30.

The LED unit 60 of the present invention includes a first LED module 61 that emits light of a first wavelength and includes a plurality of LEDs, a second LED module 62 that emits light of a second wavelength and includes a plurality of LEDs, And a third LED module 63 that emits light of a third wavelength and includes a plurality of LEDs.

The rectifying unit (10) of the present invention can rectify the commercial AC power inputted from the outside to a predetermined DC power. The rectifying unit 10 may select one of the first to third LED modules 61 to 63 according to a control signal received from the control unit 30 and provide rectified DC power to the selected LED module .

The sensor unit 20 of the present invention senses at least one of ambient sound, human motion, body temperature of a patient, and respiration of a patient, and generates a sensing signal and transmits the sensing signal to the controller 30.

The patient monitoring apparatus 50 of the present invention may output a bio-signal including at least one of an electrocardiogram signal, a blood oxygen concentration signal, and a blood pressure signal of a patient to the controller 30.

The control unit 30 of the present invention receives a sensing signal from the sensor unit 20 and receives a biological signal from the patient monitoring device 50. A control signal for controlling the light emission of the LED unit 60 can be generated based on the received sensing signal and the biological signal. The control signal may be a signal for selecting one of the first LED module 61 to the third LED module 63 based on the sensing signal and the bio-signal, and controlling the illumination pattern of the selected LED module.

According to one embodiment, when at least one of ambient sound and human motion is sensed by the sensor unit 20, the sensor unit 20 generates a first control signal for dimming the first LED module 61 And transmits the first control signal to the rectifier 10 so that the first LED module 61 can be dimmed. When the body temperature and respiration of the patient sensed by the sensor unit 20 are out of a predetermined range, a second control signal for turning on the second LED module 62 according to the first illumination pattern is generated, The second control signal may be transmitted to the rectifying unit 10 to control the second LED module 62 to be turned on. The third LED module 63 generates a third control signal to turn on the third LED module 63 according to the second illumination pattern when the bio-signal is out of a preset range, To control the third LED module 63 to be turned on.

The control signal thus generated is transmitted to the rectifying unit 10. The rectifying unit 10 selects one of the LED modules emitting light of different wavelengths according to a control signal and drives the selected LED module according to a predetermined illumination pattern .

According to an embodiment of the present invention, the first LED module 61 controls the dimming of the LED module automatically when the patient, the visitor, and the medical staff enter the hospital in daily life that simply lights the fire. Accordingly, in this case, the light of the first wavelength emitted from the first LED module 61 may be white light.

Conversely, the second LED module 62 and the third LED module 63 serve to notify the medical staff of an emergency situation when the patient is in a dangerous state. Therefore, the light emitted from the second LED module 62 and the third LED module 63 must be different in color from the light emitted from the first LED module 61. Preferably, the wavelength of the second LED module 62, which is turned on when the patient's body temperature and respiration are abnormal, may be blue, and the third LED module 62 may be turned on when the patient's electrocardiogram, blood pressure, (63) may be a red series. However, in one embodiment, the wavelength of light emitted from the second LED module 62 and the third LED module 63 may vary depending on the situation.

The illumination pattern of the present invention may be set differently according to the first to third LED modules 63, 61, 62 and 63. For example, the illumination pattern of the first LED module 61 is a dimming control method in which the illumination pattern is gradually brightened until it is completely turned on. If the illumination pattern is completely turned on, it can be controlled so as not to blink. Here, the blinking refers to turning on / off the light according to a frequency that is not noticeable by a person, and does not mean on / off of the physical illumination.

In addition, the second LED module 62 and the third LED module 63 that emit light in the emergency state of the patient need not be dimmed. Once turned on, the on / off can be controlled according to a predetermined period. For example, the second LED module 62 may be turned on and off at intervals of 0.1 to 0.5 seconds, and the third LED module 63 may be turned on and off at intervals of 0.7 to 1 second.

Claims (8)

An LED module including a plurality of LEDs;
A rectifying unit for rectifying the commercial AC power inputted from the outside and rectifying the rectified AC power to the LED module;
A sensor unit for sensing at least one of sound, motion, body temperature, and breathing to generate a sensing signal;
A patient monitoring device for detecting a biological signal including at least one of an electrocardiogram signal of a patient, a blood oxygen concentration signal, and a blood pressure signal; And
And a control unit for receiving a sensing signal and a biological signal from the sensor unit and the patient monitoring apparatus, generating a predetermined PWM control signal based on the sensing signal and the biological signal, and transmitting the PWM control signal to the rectifying unit,
Wherein the rectifying unit dims-on-controls the LED module according to the control signal. The method according to claim 1,
The control unit
An input unit for receiving and providing the sensing signal and the bio-signal;
An analysis unit for analyzing a sensing signal and a biological signal provided from the input unit and determining a dimming pattern based on the analyzed signal;
And a control signal generation unit receiving the dimming pattern from the analysis unit and generating the PWM control signal based on the dimming pattern. The method according to claim 1,
The control unit generates a first PWM control signal when at least one of sound and motion is sensed by the sensor unit and transmits the first PWM control signal to the rectifying unit to dim the LED module Features of the hospital lighting system. The method of claim 3,
Wherein the sensor unit includes a sensor for sensing at least one of body temperature and respiration of the patient,
Wherein the controller generates a second PWM control signal when at least one of a predetermined body temperature and respiration of the patient is out of a preset range,
And transmits the second PWM control signal to the rectifying unit to dim the on / off control of the LED module. 5. The method of claim 4,
Wherein the controller receives a bio-signal from the patient monitoring device, generates a third PWM control signal when the bio-signal is out of a preset range, and transmits the control signal to the rectifying unit to dim the LED module On control of the lighting system. . 6. The method of claim 5,
The control unit
Wherein the control unit sets the control level to the first step when dimming on the LED module according to the first PWM control signal,
On control of the LED module according to the second PWM control signal, sets the control level to the second step,
Wherein the controller sets the control level to the third step when the LED module is dimmed on the basis of the third PWM control signal. . A first LED module including a plurality of LEDs emitting light of a first wavelength, a second LED module emitting a light of a second wavelength and including a plurality of LEDs, and a plurality of LEDs emitting light of a third wavelength, 3 LED module including LED module
A rectifier for rectifying a commercial AC power input from the outside to a predetermined DC power and delivering the rectified AC power to at least one of the first LED module and the third LED module;
A sensor unit for sensing at least one of a surrounding sound, a motion of a person, a body temperature of the patient, and a respiration of the patient to generate a sensing signal;
A patient monitoring device for outputting a biological signal including at least one of an electrocardiogram signal of a patient, a blood oxygen concentration signal, and a blood pressure signal; And
Receives the sensing signal or the bio-signal, selects one of the first LED module and the third LED module based on the sensing signal or the bio-signal, generates a control signal for controlling the illumination pattern of the selected LED module, And a control unit for transmitting the control signal,
Wherein the rectifying part provides a direct current power to drive one selected one of the first to third LED modules in the illumination pattern according to the control signal. 8. The method of claim 7,
The control unit
A first control signal for dimming the first LED module when at least one of ambient sound and human motion is sensed by the sensor unit and transmits the first control signal to the rectifying unit, 1 LED module is dimmed on,
And generates a second control signal for turning on the second LED module according to the first illumination pattern when the body temperature and respiration of the patient sensed by the sensor unit exceed a preset range, And controls the second LED module to be turned on,
Generates a third control signal for turning on the third LED module according to a second illumination pattern when the bio-signal is out of a preset range, and transmits the third control signal to the rectifying unit, And controls the LED module to be turned on.

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