JPH04131238U - Skin-attached biological body temperature thermal stimulation device - Google Patents

Abstract

(57) [Summary] (with amendments) [Purpose] To create a device that can be miniaturized for adhesive use and can perform thermal treatment without the risk of burns, even when using a small capacity battery. suggest. [Structure] A biological body temperature thermal stimulation device having a heating element driven by a light and small battery, including a heat-retaining heating chamber structure in which the heating element is protruded, and the heating element is brought into close contact with the skin surface of the living body, and the entire device is an adhesive member for attaching the skin to the skin, a switching means for intermittent supply of electrical energy from the lightweight small battery to the heating element, and signal processing for outputting a driving pulse for driving the switching means. have the means.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

This invention is a skin-integrated electric thermal treatment that is compact but provides sufficient thermal treatment. Concerning vessels.

0002

[Conventional technology]

In order to propose an electric moxibustion device that has a small size and can be attached to the skin of a living body, we need a small A type battery must be used to generate heat from a heating element. Small batteries are button-type, coin-type, etc. small capacity batteries of 100mAh (2C) or less. It is. On the other hand, heating elements have extremely low resistance, ranging from several ohms to several tens of ohms. It's a good thing.

0003

[Problem that the idea aims to solve]

Under these circumstances, it is necessary to use a heating element to generate heat and use it as a moxibustion device or isothermal heat treatment device. The battery capacity is too small to generate enough heat to perform all kinds of treatments. was not obtained.

0004

[Means to solve the problem]

In view of the above, the present invention includes a heating element part corresponding to the moxibustion part and a heat-retaining structure surrounding it. The body is formed into a convex shape to make contact with the body's skin, and the battery energy is supplied to the heating element. The heating element is controlled intermittently through the switching element and signal processor. The fever temperature can be delicately controlled, eliminating the risk of burns and providing optimal thermal treatment. We have created a device that allows temperature settings.

[0005] The features of the present invention are as follows. A heating element that generates heat using a weak battery can perform thermal treatment only on the surface or very close to the heating element. The temperature reaches a maximum of about 70℃. Based on this knowledge, it is possible to place a heating element in contact with the skin. By adopting a configuration that allows for thermal treatment. However, heating elements do not necessarily generate appropriate heat. However, there are many cases where the temperature is even higher. prevent such cases To do this, some kind of resistance must be added.

[0006] However, for example, the resistance of the heating element is 1 (Ω) and a weak battery is used. In this case, if a general resistance of 1 (Ω) is added, the supply to the heating element is The current generated is halved, the energy is further halved, and the temperature on the surface of the heating element is lower than that of the body. It doesn't go up enough that I can feel it.

[0007] On the other hand, active devices that sense temperature and perform switching operations, such as thermostats, It is possible to use an element, but the switching operation of a thermostat is proportional to the temperature. It is an analog operation that gradually turns on and off, and the on-resistance is at least several (Ω), so the thermostat itself consumes energy. It is less practical. Unlike a thermostat, a transistor uses the output of an external oscillator. This device performs forced on/off digitally in response to high on-resistance. Since there are a lot of them, those with low on-resistance must be selectively used.

[0008] In this invention, a transistor with low on-resistance, FET (field effect transistor) , the use of relays is preferred.

[0009] The above switching element is activated by the drive pulse output from the signal processor. It is passively turned on and off (driven). The frequency and duty of this drive pulse are By adjusting the temperature, the heat generation temperature of the heating element can be finely adjusted.

0010 In this way, the heating element is attached to the skin, and the heat generated by the heating element is generated from a micro battery. By intermittent control of electrical energy supplied to the body, it is safe and effective. Heat treatment is administered. Furthermore, the current supplied to the heating element when the above intermittent control is connected and disconnected also depends on the connection. The connection and cut-off are performed, but by frequently switching on and off, the heat generation temperature can be controlled in an analog manner. The temperature of the heating element, such as a timer or thermostat, may rise. , shut off when the predetermined time comes, or when the temperature drops or the predetermined time comes. This is different from the intermittent control of connecting.

[0011] Moreover, by gradually changing the frequency and duty of this pulse, A more effective treatment that can imitate the unique fever pattern of “Mogusa” moxibustion. This is what the device can achieve. Signal processors are typically microcontrollers, but there are also other types of signal processors. Any device can be used as long as the frequency and duty of the signal can be adjusted. You can. The heat used in this invention includes warm moxibustion, moxibustion, etc.

0012

【Example】

Figure 1 is a diagram showing an embodiment of the present invention, and shows a further enlarged view of the vicinity of the heating element. It is shown in FIG. In Figure 1, (1) is the main body case (or called the main body), which has a hard It is formed by ticks, etc. There are batteries and electronic chips inside the main body case (1). A mounted board is built-in. (2) is a battery. Batteries (2) are coin-shaped, both rechargeable and non-rechargeable. , button type, pin type, etc., but any small, lightweight, and low capacity battery may be used. (3) is the board on which IC, resistor, and capacitor chips are mounted and mounted. It is. The substrate (3) and battery (2) are connected via conductive members (21) and (22). It is continued. (4) is a heating element with two conductive terminals (41) (4) on both sides. 2) Protrudingly arranged. The heating element (4) is made of nichrome wire, platinum wire, or tungsten. It is made of wire, etc., but apart from this, it is made of platinum, gold, silver, copper, silver-palladium, etc. This shows a ceramic plate coated with a ceramic plate. As an example, A Lamix heater (manufactured by Cymarex) is shown. FIG. 8 is an enlarged view of the vicinity of the heating element (4). Figure 8 also shows heat retention and low heat generation. This is also an example of a room. The conductive terminals (41) and (42) each penetrate the substrate (3), The tops of the conductive terminals (41) and (42) are connected to the conductive plate (31) fixed to the substrate (3). , (32). A heat conducting portion (5) is attached to the lower surface of the heating element (4). The heat conducting part (5) is It is mainly made of ceramics and metals such as titanium. The heating element (4) and the heat conducting part ( 5) may be collectively referred to as a heating element. A heat retaining member with excellent heat retention and insulation properties is installed around the heating element (4) and the heat conduction part (5). (6) is placed. The heat retaining member (6) is, for example, paper, wood, ceramics, Examples include plastics and resins. In addition, the heat resistance of the heat insulating member should be around ~80℃, and there is no need to particularly limit the material. There isn't. The heat conducting portion (5) has a height that projects (convexes) from the bottom surface of the main body (1). Irregularities may be formed on the surface of the heat conducting portion (5). Further, a plurality of protrusions (7) are formed on the outer peripheral surface of the main body (1). (8) is a bandage. The bandage (8) is formed into a ring shape and is made of a sponge, etc. An adhesive (82) is placed on a somewhat thick flexible support member (81). The composition of the adhesive (82) is not particularly specified, and may be used as a medical adhesive or other biological adhesive. It is fine as long as it is harmless.

[0013] The embodiment shown in FIG. 1 shows a state in which the main body (1) and the bandage (8) have already been fitted. , Before use, the main body (1) and bandage (8) are handled separately, and when used. , as shown in Figure 4, insert the bandage (8) from the top of the main body (1) and integrate it. It is attached and fixed to the affected area. It should be noted that when used, there is no need to be limited to the above-mentioned adhesion order. The shape of the bandage is The present invention is not limited to this, and any material that can fix the main body to the affected area may be used. Moreover, the shape of the main body (1) is also similar. When the main body (1) is attached and fixed to the surface of the living body, the protruding heat conductive part (5) and the skin are separated. Form sufficient contact. This state is shown in FIG. In addition, the protruding part is a heat conductor. The heat retaining member may also protrude together with the heat conducting portion. Since the heat conducting part (5) and the biological skin (MM) form a sufficient contact state, the heat conducting part (5) Heat generated from the heating part (5) can be sufficiently applied to the skin of the living body. Furthermore, heat conduction Part (5) If the surface is made uneven, the heat radiation efficiency will increase and the heat generated by air will increase. It can relieve feelings.

[0014] The embodiment shown in Fig. 2 has a disc shape, whereas the embodiment shown in Fig. 1 has a disc shape. It has a high cylindrical shape. Further, the embodiment shown in FIG. 2 includes a heating element and surrounding The heat retaining member protrudes and has elasticity in the upper and lower directions. In addition, the embodiment shown in Figure 2 can reduce the area of contact with the skin, thereby reducing the It also makes it easier for the heating body or heat conducting part to come into contact with the pressure points of the living body.

[0015] (1) is the main body case, which is made of hard resin, plastic, or the like. A battery and a board are built inside the main body case (1). (2) is a battery, which may be rechargeable or non-rechargeable, and may be button-shaped, coin-shaped, pin-shaped, etc. It is a small battery with low capacity. (3) is the substrate, which is a chipped capacitor, resistor, IC, and transistor. , coils, etc. are mounted. The substrate (3) and the battery (2) are connected to a conductive member (2). 1) Connected via (22). (4) is a heating element, which conducts a paste of platinum, gold, silver, copper, silver-palladium, etc. A layered body is formed by printing and baking coating on the heating element, and there are two conductive terminals on both ends. (41) and (42) are arranged protrudingly. (5) is a heat conductor and is also the base of the heating element (4). The material is ceramic This is common, but it is not limited to this. (6) is a heat insulating tank (heat insulating member), with the heating element (4) and the heat conducting part (5) facing downward. It is surrounded except for the direction. The conductive terminals (41) and (42) pass through the heat insulating tank (6) and have one end fixed to the substrate (3). The other ends of the conductive plates (31) and (32) are connected to each other. Conductive plate (31) (32 ) is fixed at one end, so the other end is elastic. The conductive plates (31) and (32) serve as output ends of the electronic circuit operating on the substrate (3). Connected. For joining conductive plates (31) (32) and conductive terminals (41) (42) Electrical energy is supplied to the heating element (4), and the heating element (4) and heat insulation are It gives vertical elasticity to the tank (6). (8) is a bandage. The bandage (8) has a cylindrical shape and a bottom extending toward the outer circumference. An adhesive (82) is disposed on a flexible support member (81) having a similar shape. Adhesive (82) , as long as it is placed at least on the part that comes into contact with the living body, but it is also possible to place it on the body and the bandage. Adhesive may also be placed on the contact area to improve bonding between the main body and the bandage. . The usage example of the embodiment shown in FIG. 2 is the same as that in FIG. 1, so the explanation is omitted. Note that, unlike FIG. 1, the embodiment shown in FIG. Because of this, it can easily come into contact with living organisms.

[0016] FIG. 6 shows an example of an electronic circuit wired on the substrate of the embodiment shown in FIGS. 1 and 2. . (61) is a battery, which is the same as battery (2) shown in FIGS. 1 and 2. (62) is for inputting battery voltage to terminal (a) in a DC/DC converter. , which outputs the boosted voltage to the terminal (b). (DC/DC converter Example: RH5RC: manufactured by Ricoh Co., Ltd.) (63) is a switching element, and an FET is mainly used. On resistance is For example, it is about 0.3 (Ω). Those with low on-resistance are preferable, especially FETs. However, the present invention is not limited to , and transistors, relays, etc. may also be used. Switching element (6 3) is the connection between terminal (c) and terminal (d) using the signal of terminal (e). It is something that can be separated or separated. (64) is a microcomputer, which is connected to the terminal (e) of the switching element (63). It supplies drive pulses. The microcomputer (64) has a built-in program. , outputs drive pulses based on this program. For example, one chip machine Ikon μPD-7554 etc. are exemplified. The output frequency of the drive pulse is 5 ( Hz) to about 50 (Hz). In addition, the above frequency was selected in order to finely adjust the frequency and due to the capacity of the program. However, it is not limited to this. (65) is a heating element, which is the heating element described in the above embodiment. The (+) side of the battery (61) is connected to terminal (a) and terminal (c), and terminal (d) is connected to terminal (a) and terminal (c). It is connected to one end of the heater (65). The (-) side of the battery (61) is DC/DC Converter (62), microcomputer (64), and other ends and terminals of heater (65) (f) is connected. Terminal (b) is connected to the power input of the microcomputer. terminal (a) to (f) are provided merely to explain the configuration and operation of this electronic circuit. Ru.

[0017] Next, the operation will be explained. The battery (61) supplies energy to the DC/DC converter (62) via the terminal (a). supply ghee. The DC/DC converter (62) converts the energy supplied from the battery (61) into The voltage is boosted, smoothed, and the boost energy is supplied to the microcomputer (64) via the terminal (b). supply. The microcomputer (64) operates by supplying this boosted energy and The eve pulse is supplied to the switching element (63) via the terminal (e). The switching element (63) establishes an electrical connection between the terminal (c) and the terminal (d). It is opened and closed by a drive pulse input from terminal (e). When the terminal (c) and terminal (d) are closed, the energy of the battery (61) generates heat. It is supplied to the body (65) and shut off when opened. The heating element (65) generates heat when supplied with electrical energy from the battery (61). When the supply is cut off, the heating operation stops. repeat this multiple times As a result, one heating pattern is formed. This operation is shown in FIG. Figure 7(a) shows The square wave drive pulse output from the icon, Figure 7(b) shows the heating pattern of the heating element. It is. The time of one heat generation pattern is about 1 second to 120 seconds, and the maximum temperature is The standard temperature is about 60°C to 70°C. Figure 7 shows the frequency of the microcomputer drive pulse. Increasing the value will increase the heat generation temperature of the heating element, and decreasing the frequency will decrease it. It is shown that. The frequency of the drive pulse is about several (Hz) to several hundred (Hz) , Duty is 0 to 100 (%). Note that the heat generation pattern and drive pulse output pattern in Figure 7 are just examples; Various heating patterns can be formed by setting the pulse width and pulse interval of the eve pulse. Ru. Especially when the pulse width (Duty) is kept constant and only the pulse interval is changed. , the heating element can generate heat with a smooth heating pattern. The microcomputer program determines the pulse interval of the drive pulses output from the microcomputer, The explanation is omitted because it widens or narrows the pulse width. When the battery voltage further decreases, the DC/DC converter (62) stops operating and the master The operation of the icon (64) also stops, the switching element (63) turns off, and the Thermal operation also stops.

[0018] As is clear from the above explanation of operation, microcontrollers can perform switching with low on-resistance. This example circuit allows you to arbitrarily control the heat generation temperature of the heating element by driving the element. One of the features is that the loss of energy is suppressed as much as possible. Note that the use of a microcontroller is just an example; the microcontroller oscillates pulses and It may be anything that can provide an output similar to that of the login function. In addition, the degree of protrusion of the heating element is from 0 (mm) to several tens (mm), and the heating element and the skin of the living body are close to each other. Just contact is sufficient. Also, instead of using a bandage, adhesive is placed on the main body. You can.

[0019]

[Effect of the idea]

As described in detail above, the present invention has a heating element and a surrounding insulation chamber arranged in a protruding manner, and an adhesive part. By attaching the device itself to the living body's skin using a material, the heating element can be closely attached to the living body's skin. Since it uses a small battery, it can provide sufficient heat even when only a weak amount of heat is generated. Heat treatment is possible, and the switching element is driven by the signal processing means to generate the heating element. Since the heat temperature can be controlled arbitrarily, excessive temperature rise caused by the protruding arrangement of the heating element can be avoided. It has the effect of being able to prevent such damage. It should be noted that the present invention may have any structure as long as it has the above-mentioned effects; Adding a high-precision resistor with a resistance value of a fraction of a second suppresses the upper limit of heat generation temperature. The present invention also includes the case where a means is added.

[Brief explanation of drawings]

[Figure 1]

FIG. 2 is a cross-sectional view of an embodiment of the present invention.

[Figure 3]

FIG. 5 is a diagram illustrating a case where the present invention is actually implemented.

FIG. 4 is a perspective view of the embodiment shown in FIG. 1;

FIG. 6 is a diagram showing an electronic circuit used in the embodiment shown in FIGS. 1 and 2;

7 is a diagram showing output waveforms of various parts of the electronic circuit shown in FIG. 6. FIG.

8 is a cross-sectional view showing the vicinity of the heating element (heat-retaining heating chamber) of the embodiment shown in FIG. 1. FIG.

[Explanation of symbols]

1. main body case 2. battery 3. substrate 4. heating element 5. Heat conduction part 7. protrusion 8. bandage MM, biological skin

──────────────────────────────────────────────── ─── Continuation of front page (72) Creator Yasuhiro Matsuyama Sky Heights Hijikata, 625 Misawa, Hino City, Tokyo 210

Claims (1)

[Scope of utility model registration request] 1. A biological body temperature thermal stimulation device having a heating element driven by a lightweight small battery, comprising: a heat-retaining heat generating chamber structure in which the heating element is disposed in a protruding manner; A switching means for intermittent supply of electrical energy to the heating element from an adhesive member for attaching the entire device to the skin and the small lightweight battery, and a driving pulse for driving the switching means is outputted. A skin-integrated body temperature stimulation device characterized by having a signal processing means.