JP7512619B2 - Dimming System - Google Patents

Description

The present invention relates to an improved light control system for curtains that are suitable for partitioning multiple beds in hospital rooms, nursing homes, etc.

In hospital rooms and nursing facilities (hereinafter referred to as "patients" and "hospital rooms") where multiple patients or residents share a room and have multiple beds, the beds can be separated by curtains that can be opened and closed freely to protect the privacy of patients when they are changing clothes, etc. However, if the curtains are closed completely and completely block the view, it is not possible to peek at the patient's condition, and there is a risk that a sudden change in the patient's condition or the occurrence of an accident will not be discovered until it is too late.

As a proposal for improving hospital room curtains to reduce the risk of overlooking changes in the patient's condition, a configuration in which a see-through section is formed only at the top along the entire width direction is known. With this curtain, when the patient is standing up, the other side of the curtain can be seen through the see-through section, but when the patient is sitting or lying down, the line of sight shifts from the see-through section and the patient is unable to see what is happening inside, resulting in a change in vision according to the line of sight. (See Patent Document 1)

Japanese Patent Application Laid-Open No. 11-32903

The curtains in Patent Document 1 always allow malicious peeking and do not provide sufficient privacy protection. Even if the patient behind the curtains can be seen, it is not guaranteed that the patient will notice any abnormalities, such as a change in their condition. The present invention proposes a light control system that not only ensures protection of patient privacy, but also dramatically improves the appeal and alert effect in calling attention to various abnormalities, such as changes in the patient's condition.

The dimming system according to the present invention comprises:
A curtain that encloses a sleeping space and has a light control film that can switch the transmittance to two or more levels depending on an applied voltage;
An acquisition means for acquiring at least one type of data relating to a health condition of a user;
and a drive control means for switching the transmittance of the light control film based on the data acquired by the acquisition means.

The present invention is not limited to partitions between multiple beds in hospital rooms, nursing homes, etc., but can also be applied to "sleeping spaces" with futons and sofas, and use by "users" other than patients is also anticipated, so the above expression has been adopted.

It may also be possible to provide a notification means for notifying a third party other than the user of the presence of the light control film by a means other than switching the transmittance of the light control film based on the data acquired by the acquisition means.

The curtain may also be suspended and have a curtain rail section that supplies power to the curtain.

The light control film has a flexible structure in which a light control layer is sandwiched between flexible transparent substrate films on which at least transparent electrodes are formed, with the transparent electrodes facing each other, and
The curtain is preferably a Noren-style curtain having a slit extending in the height direction in a normal use state.

The light-controlling layer is preferably either a polymer-dispersed liquid crystal in which liquid crystal molecules are dispersed in a polymer, or a polymer-network-type liquid crystal in which liquid crystal molecules are arranged in voids formed inside a polymer network made of a resin formed into a three-dimensional mesh.

The light control system of the present invention not only ensures that the privacy of the patient (or user) in the sleep space is protected, but also dramatically improves the effectiveness of appeals and alerts to alert the patient to various abnormalities, such as changes in the patient's condition. Not only can the patient themselves send out SOS signals, but by detecting and assessing various data related to the patient's condition, it is possible to clearly inform the patient of the occurrence of abnormalities that the patient is not aware of.

FIG. 1 is a block diagram showing a configuration of a light control system according to an example of the present invention. FIG. 4 is a diagram showing a data table recorded in a data processing unit. FIG. 2 is an explanatory diagram showing a curtain of a light control system in a high haze (opaque) state. FIG. 2 is an explanatory diagram showing the curtain of the dimming system in a low haze (transparent) state. 1 is a diagram showing an example of a state in which a patient is carried out of bed. FIG. 2 is a cross-sectional view showing the layer structure of a light control film. FIG. 4 is an enlarged cross-sectional view showing an example of the structure of a power supply section to the light control film. FIG. 1 is an explanatory diagram showing an example of use of a light control system (curtain 1). FIG. 1 is an explanatory diagram showing an example of use of the dimming system (curtain 2).

Below, an embodiment of the present invention relating to a partition in a hospital room equipped with beds will be described with reference to the drawings. Figure 1 is a block diagram showing the configuration of a light control system 10 according to an example of the present invention.

The light control system 10 includes a curtain 11 used as a partition surrounding a bed in a hospital room, a sensor 14 that acquires various data related to the patient's health condition, a data processing unit 12 that analyzes the various data acquired from the sensor 14 to determine whether or not there is an abnormality, and a main CPU 13 that switches the transmittance of the light control film 11 based on the results of the determination by the data processing unit 12.

The sensor 14 is provided at the bedside and acquires various data related to the health condition of the patient measured at the bed. The various data include electrocardiogram (arrhythmia and ischemia), respiration, blood pressure, _SpO2 (data from a pulse oximeter that monitors the pulse rate and percutaneous arterial blood oxygen saturation in real time by attaching a detector (probe) to the fingertip or earlobe) depending on the patient's condition, and other data such as body temperature and infusion status are appropriately measured to acquire at least one type of data related to the user's health condition. When a doctor, nurse, or laboratory technician collects data beside the patient, it is easy to immediately grasp abnormal values, but for abnormalities that occur during measurement of data that the patient can measure by himself, such as blood pressure and body temperature, the importance of an abnormality occurrence alert linked to the data processing unit 12 and main CPU 13 described later increases.

It would also be effective to incorporate a nurse call button into the system so that, when various data is not being measured, the patient can notify the nurse of any abnormal changes they notice, the end of their infusion, or a request to be called.

The data processing unit 12 compares the various data acquired about the patient's health condition with pre-set normal value data, and if a deviation of a specified amount or more is found, it judges it to be an abnormal value (= abnormality). The results of each measurement, including the data judgment results, are stored in a patient database 17, which stores patient information (medical records) including the pre-set normal value data, and the judgment results are sent to the main CPU 13.

Fig. 2 is a diagram showing a data table recorded in the data processing unit 12. As shown in Fig. 2, the patient data registered and managed in the data processing unit 12 is stored as a table of various information registered at the beginning of the examination related to each patient's electrocardiogram, respiration, blood pressure, _SpO2 , etc. Here, ID refers to identification number data unique to the patient, such as name, sex, age, disease name, and attending physician. The data processing unit 12 holds normal values as targets set by the attending physician from the data related to the various information registered at the beginning of the examination as a data table, and compares them with the measurement results transmitted each time.

When an abnormal value (= abnormality) determination result is sent to the main CPU 13, if the curtain (light-adjusting film) is closed and opaque, the drive control means for switching the transmittance of the light-adjusting film is driven in accordance with a command from the main CPU 13 so that the light-adjusting film becomes transparent.

Alternatively, when the patient presses the nurse call button, and the main CPU 13 detects the button operation, if the curtain (light-adjusting film) is closed and opaque, the light-adjusting film is driven to become transparent.

Figure 3 is an explanatory diagram showing the case where the curtains 11 of the light control system 10 are in a high haze (opaque) state under normal circumstances when there is nothing wrong with the patient. Because the curtains 11 around the bed are closed and opaque, it is not possible to see what is happening inside, and the patient's privacy is protected.

Figure 4 is an explanatory diagram showing the case where the curtains 11 of the light control system 10 are in a low haze (transparent) state in an emergency when something unusual happens to the patient. The curtains 11 around the bed turn transparent, allowing the inside to be seen from outside.

Not only do the curtains 11 turn transparent in an emergency, but by providing a means for notifying people other than the patient of the presence of the patient through a means other than switching the transmittance of the light-control film, information about an abnormality is instantly transmitted to the outside of the room. This system is linked to the nurse call button, so that even if the nurse call button is not pressed, a signal can be sent to the nurse center (or an announcement of an abnormality can be made through a different notification means) in the same way as if the nurse call button had been pressed.

Figure 5 is a diagram showing an example of a state in which a patient is carried out of bed. People other than the patient are not shown. In this diagram, a patient on a stretcher or bed with casters is shown being carried out of the curtain in direction a, but carrying in direction b is also possible. In order to carry the patient out instantly in this manner without opening a closed curtain, it is advantageous for the curtain to be a noren-style curtain made of a flexible material. In this respect, a curtain made of highly flexible light-controlling film is extremely suitable.

<Light control film>
The light control layer of the light control film constituting the curtain 11, which is the main part of the light control system 10, is configured by sandwiching liquid crystal molecules between substrates having electrodes arranged at a certain interval and further sandwiching these between two polarizing plates, and any of the TN type, VA type, and IPS type can be adopted, which perform display by modulating the light-transmitting state/light-shielding state on a cell (pixel) basis by changing the transmittance of polarized light by electrically driving the liquid crystal. In the present invention, since the light control film is used in the form of a curtain, it is necessary to have a sufficient structure with sufficient flexibility overall, and a resin film is adopted as the substrate.

In this embodiment, rather than switching between a light-transmitting state and a light-blocking state, it is preferable to employ a liquid crystal display element that switches between a liquid crystal transmission state (transparent state) and a scattering state (opaque state) as a liquid crystal display element with high light utilization efficiency without using a polarizing plate. Representative examples are polymer network liquid crystal (PNLC: Polymer Network Liquid Crystal) configured with liquid crystal molecules arranged in voids formed inside a polymer network made of resin formed into a three-dimensional mesh, or polymer dispersed liquid crystal (PDLC: Polymer Dispersed Liquid Crystal) configured with liquid crystal molecules dispersed in a polymer, and PNLC will be described below.

To manufacture a light-control film with a light-control layer made of PNLC, a mixture of liquid crystal and a photopolymerizable compound (monomer) is sandwiched between a pair of transparent electrode substrates and irradiated with ultraviolet light under certain conditions. The photopolymerizable compound is converted into a polymer by photopolymerization, and a polymer network with countless fine domains (voids in the polymer) is formed in the liquid crystal by photopolymerization and crosslinking.

The driving voltage of a PNLC generally depends on the structural characteristics of the polymer network (such as the size and shape of the domains, and the film thickness of the polymer network), and the driving voltage is determined based on the relationship between the structure of the polymer network and the resulting light transmission and scattering degree. In order to construct a PNLC that can obtain sufficient light transmission and scattering degree in a voltage range of 100 V or less, it is necessary to form the polymer network so that each domain is uniform in size and shape. In the present invention, the domain size, which depends on the polymer network structure, is controlled to 3 μm or less, preferably 2 μm or less, and more preferably about 1 μm.

As shown in FIG. 6, the light control film 50 includes a light control layer 52 made of PNLC and transparent conductive films 53 (a, b). The transparent conductive films 53 (a, b) sandwich the light control layer 52 (PNLC), and a voltage is applied from a power supply unit (not shown) to the light control layer 52 (PNLC) to change between high haze (scattering state) and low haze (transmitting state).

The light control layer 52 is preferably manufactured to a thickness of 5 μm to 50 μm (preferably about 10 μm to 25 μm). The transparent conductive film 53 is formed by depositing transparent electrodes 56 made of a transparent conductive material such as ITO, IZO, or an organic conductive film on a transparent substrate 55, and sandwiches the light control layer 52 with the transparent electrodes 56 facing each other. The preferred thickness of the transparent electrodes 56 is approximately 80 nm to 150 nm. In addition, with PNLC, it is also possible to express any intermediate tone haze state depending on the applied voltage.

If desired, patterning of the transparent electrode 56 is required, which can be performed by any method, such as etching, lift-off, laser trimming, or methods using various masks.

The light control layer 52 made of liquid crystal elements is known to have two types of modes, normal mode and reverse mode, depending on the manner of use. The normal mode refers to a mode in which the light is transmitted when a voltage is applied (ON) and is in a scattering state when the voltage is removed (OFF). The reverse mode refers to a mode in which the light is transmitted when the voltage is removed (OFF) and is in a scattering state when the voltage is applied (ON). In the case of the reverse mode, a film substrate with an alignment film formed on the transparent electrode 56 is required. As long as the alignment film is a conventionally known alignment film, either a horizontal alignment film or a vertical alignment film may be used, and can be appropriately selected depending on the application.

The light control film 50 is expected to be used in a manner in which its transmittance is modulated so that it is normally in a low haze state and switches to a high haze state when an abnormality occurs. In this case, the reverse mode light control layer has an advantage in terms of reducing power consumption.

The transparent substrate 55 constituting the transparent conductive film 53 can be made of polyethylene terephthalate (PET) film, polyethylene (PE) film, polycarbonate (PC) film, or the like. The thickness of the transparent substrate 55 is preferably about 50 to 200 μm.

The transparent conductive layer 56 constituting the transparent conductive film 53 is generally made of a metal oxide such as ITO, but it is also possible to use a low-resistance conductive polymer instead of ITO. As the conductive polymer, it is preferable to use a material containing a polyanion doped into a π-conjugated conductive polymer such as PEDOT/PSS.

The transparent electrode 56 made of ITO, IZO, or an organic conductive film does not adhere to solder, so to enable soldering, a terminal treatment that acts as an intermediary is required, such as forming a metal plating layer (typically Ni) on the transparent electrode or forming a thick film layer using a conductive adhesive.

<Light control system>
A light control system 10 to which the light control film 50 is applied will be described with reference to FIGS.

In one example of a method for forming a power supply section for applying a voltage to the light control layer 52 (PNLC), a connection terminal (power supply section) 70 is formed by using silver paste, carbon tape, and copper tape to further increase adhesive strength on the surface of the transparent base material 55, the transparent conductive layer 56 (including the alignment film in the case of reverse mode), and the transparent conductive layer 56 exposed by cutting out the light control layer 52 at each end of the transparent conductive film 53 (a, b), and is connected to a power source (not shown) by wiring routed via solder. The power supply section 70 (a) formed on one transparent conductive film side is formed at a location separated from the power supply section 70 (b) formed on the other transparent conductive film side without overlapping. In this way, a voltage is applied from the power supply section 70 provided to the transparent conductive film 53, and the liquid crystal of the light control film 50 is driven. (Fig. 7)
In this system, a flexible, large-area light control film 50 is used by hanging it from a curtain rail in the form of a curtain 11 (FIG. 8). The curtain 11 may be a single continuous piece, or a plurality of independent light control films 50 may be arranged on two or three sides (excluding the wall side on the pillow side out of the four sides) of a rectangle surrounding the bed. It is preferable to supply power to the connection terminal (power supply unit) 70 from a power source (not shown) routed through the curtain rail. In FIG. 8, the main CPU 13 that drives the light control film 50 (curtain 11) is also shown installed on the curtain rail, but the location of the main CPU 13 is not limited thereto, and it may be installed in the same place as the bedside monitor. Alternatively, it may be installed in the same place as the data processing unit 12 (not shown).

Figure 8 (a) is an overview of the side view of the curtain 11 when it is normally closed. The curtain 11 (light-adjusting film 50) is opaque, and the inside of the curtain cannot be seen. Figure 8 (b) shows the state when the curtain is opened, when the transmittance of the curtain 11 (light-adjusting film 50) changes to a transparent state in response to the operation of the data processing unit 12 and main CPU 13 of the light-adjusting system 10 due to an abnormality occurring in the patient, making the inside of the curtain visible.

Although the curtain 11 is flexible, it is made mainly of a resin film, and is not as light and flexible as a cloth curtain, so when opening and closing it, it is folded up by alternating mountain folds and valley folds like an accordion curtain. In the figure, the connection terminal (power supply unit) 70 and main CPU 13 are exaggerated, so the opening and closing stroke is drawn to be about half the total length of the curtain, but the actual opening and closing stroke can be made much greater.

In addition, in FIG. 8, the large-area curtain-sized light-control film 50 has only one connection terminal (power supply unit) 70 at the top left (one set of electrodes on the front and back). Depending on the distance from the connection terminal (power supply unit) 70, a voltage gradient occurs on the transparent electrode layer of the light-control film, which switches the display state of the light-control film 50 between an opaque state and a transparent state. The larger the light-control film, the more noticeable the unevenness in the display state due to the voltage gradient. Therefore, when the light-control film to be driven is large in area, the drive voltage must be increased.

The unevenness of the display state due to the voltage gradient is caused by the high wiring resistance of the transparent electrode layer. To solve the problem of the degree of light scattering (transmittance) being non-uniform for each light control film region due to differences in applied voltage, the following methods are appropriately adopted as necessary.
a) A transparent electrode layer having a high wiring resistance is partially supported (to the extent that the view due to transparency is not obstructed) by a conductive material having a low wiring resistance.
b) Form connection terminals (power supply parts) at multiple locations.

Fig. 9 shows a modified example of the present system constructed with a curtain shape different from that of Fig. 8. Fig. 9(a) is an overview seen from the side in a state where the curtain 11 is closed in a normal state.
Fig. 9(b) shows a state in which the transmittance of the curtain 11 (light-adjusting film 50) is switched to a transparent state in response to the operation of the data processing unit 12 and main CPU 13 of the light-adjusting system 10 due to an abnormality in the patient, and the inside of the curtain can be seen. The curtain 11 (light-adjusting film 50) in Fig. 9 is in the form of a noren-style curtain with a slit extending in the height direction.

Even if the light-control film 50 of the present invention is slit or partially cut and hollowed out, the function of modulating the transmittance by driving the light-control layer 52 is not impaired as long as electricity is passed through the light-control layer 52 by the transparent electrodes 56 that are sandwiched between the front and back of the film.

When opening and closing the curtain 11, in addition to sliding it from side to side on the curtain rail, it can also be handled like a Noren curtain and opened and closed (or passed under) as indicated by the arrow in Figure 9. Noren-style curtains have the advantage of allowing quiet entrance and exit without making sliding noise, and as shown in Figure 5, allowing patients with abnormal conditions to be quickly removed from any location.

10 Light control system 11 Curtain 12 Data processing unit 13 Main CPU
14 Sensor 15 Nurse call button 16 Speaker 17 Patient database 50 Light control film 52 Light control layer 53 (a, b) Transparent conductive film 55 (a, b) Transparent substrate 56 (a, b) Transparent electrode 70 Power supply section

Claims (4)

A curtain that encloses a sleeping space and has a light control film that can switch the transmittance to two or more levels depending on an applied voltage;
An acquisition means for acquiring at least one type of data relating to a health condition of a user;
A drive control means for switching the transmittance of the light control film based on the data acquired by the acquisition means,
The light control film has a flexible structure in which a light control layer is sandwiched between flexible transparent substrate films on which at least transparent electrodes are formed, with the transparent electrodes facing each other, and
The curtain is flexible;
A light control system , wherein the curtain is a Noren-style curtain having a slit extending in the height direction in a normal use state . A curtain that encloses a sleeping space and has a light control film that can switch the transmittance to two or more levels depending on an applied voltage;
An acquisition means for acquiring at least one type of data relating to a health condition of a user;
A drive control means for switching the transmittance of the light control film based on the data acquired by the acquisition means,
The light control film has a flexible structure in which a light control layer is sandwiched between flexible transparent substrate films on which at least transparent electrodes are formed, with the transparent electrodes facing each other, and
The curtain is flexible;
A light control system, wherein the curtain has a folded shape in which mountain folds and valley folds are alternately repeated when the curtain is in an open state. The light control system according to claim 1 or 2, characterized in that it is provided with an alarm means for notifying a third party other than the user of its presence by a means other than switching the transmittance of the light control film based on the data acquired by the acquisition means. 4. The light control system according to claim 1, further comprising a curtain rail unit for supplying power to the curtain while suspending the curtain.