KR20070056928A - Temperature control mat - Google Patents

Abstract

A temperature control mat is provided to control a temperature of the mat by forming an air circulating path on an inner portion of the mat to circulate the air and to control the temperature of the air at the same time. The temperature control mat includes air circulating members(10,16) for forcibly circulating air in an air circulating path, temperature control members(8,9) controlling a temperature of a user's body on temperature control areas(2,3) of the mat by controlling the temperature of the air circulating in the air circulating path, a body temperature sensing member sensing the temperature of the user's body on the temperature control areas, and a controller controlling operations of the air circulating members and the temperature control members to set the temperature of the user's body on the temperature control areas to a predetermined temperature on the basis of the value sensed by the body temperature sensing member.

Description

TEMPERATURE CONTROL MAT}

1 is a perspective view showing an appearance example of a temperature adjusting mat of the first embodiment.

FIG. 2 is a cross-sectional view of the A-A portion of the temperature control mat of FIG.

3A is an exploded view for explaining the internal configuration of the temperature adjusting mat of the first embodiment.

FIG. 3B is a plan view of the lower air flow unit shown in FIG. 3A.

FIG. 4 is a model diagram showing an example of a structure of an upper air distribution means constituting the temperature adjusting mat of the first embodiment.

5A is a model for explaining an example of the configuration of the heat exchange means.

5B is a schematic cross-sectional view for explaining an example of the configuration of the heat transfer means thermally connected to the heat exchange means.

6 is a model diagram for explaining another configuration example of the heat exchange means.

7A is a graph for explaining an example of the data processing operation of the body temperature data processing unit of the control unit provided in the temperature adjusting mat of the first embodiment.

FIG. 7B is a graph for explaining an example of a control operation relating to body temperature adjustment of the control unit installed in the temperature adjusting mat of the first embodiment.

Fig. 8 is a block diagram for explaining an example of the control arrangement provided in the temperature adjusting mat of the first embodiment.

9A is a model diagram for describing the second embodiment.

Fig. 9B is a graph for explaining an example of the control operation of the temperature adjusting mat for adjusting the temperature of the body on the temperature adjusting mat according to the present invention.

10 is a plan view for explaining a temperature adjusting mat of the third embodiment.

Fig. 11 is a schematic exploded view for explaining the internal structure of the temperature adjusting mat of the third embodiment.

12A is an exploded perspective view for explaining an example of the configuration of a temperature adjusting unit constituting the temperature adjusting mat of the third embodiment.

12B is a cross-sectional view showing a state in which the temperature adjusting unit shown in FIG. 12A is incorporated in a temperature adjusting mat.

13A is a cross-sectional view showing an example of a configuration of a far infrared heater that is one of heating means.

13B is a cross-sectional view showing an example of the configuration of a near infrared heater that is one of heating means.

14A is a view for explaining an example of the configuration of another temperature adjusting unit constituting the temperature adjusting mat of the third embodiment.

FIG. 14B is a cross-sectional view showing a state in which the temperature adjusting unit shown in FIG. 14A is incorporated in a temperature adjusting mat. FIG.

15 is a diagram for explaining a temperature adjusting mat of the sixth embodiment.

16 is a plan view for explaining an example of the arrangement positions of the body temperature detecting means and the body pressure detecting means constituting the temperature adjusting mat of the fourth embodiment.

17 is a sectional view showing an example of an internal configuration of a temperature adjusting mat of the fourth embodiment.

18 is a view for explaining an example of a control operation relating to temperature adjustment of the body in the fourth embodiment.

19 is a block diagram for explaining an example of a control configuration of a control unit constituting the temperature adjusting mat of the fourth embodiment.

20 is a view for explaining a temperature adjusting mat of the fifth embodiment.

21 is a view for explaining an example of another form of the upper air distribution means.

22 is a diagram for explaining another embodiment.

23 is a schematic sectional view for explaining another configuration example of the temperature adjusting unit.

24A is a model diagram for explaining a temperature adjusting mat of another embodiment according to the present invention.

24B is a schematic cross-sectional view for illustrating an example of the internal configuration of the temperature adjusting mat shown in FIG. 24A.

25 is a view for explaining another embodiment.

(Explanation of the sign)

1 Temperature control mat 4 Control unit

5 Upper air distribution means 6 Lower air distribution means

７ Channel control means ９ ， ９ Heat exchange means

14,15,56 temperature sensor

36 Ambient air sensor 4 Humidity sensor

５７ Body pressure detection means 60 Exit

６1 Open air intake ７８，７９ Heat exchange unit

TECHNICAL FIELD The present invention relates to a temperature adjusting mat having a temperature adjusting function such as a bed linen or a bed for sleeping, a mattress used for medical treatment including rehabilitation, nursing care or emergency care for non-sleeping purposes, or a sofa. will be.

In recent years, as the society matures and aging, an increasing number of people contribute to maintaining and promoting a healthy body. In addition, there are a growing number of people who complain of cold or aching local parts of the body, such as knees and shoulders, even if they are generally healthy. These people use tools that incorporate a heater, take medicines, take hot baths, or use hot packs or massage equipment to improve metabolism in everyday life and improve blood circulation. Relieves symptoms of sunburn and sore lesions.

(Patent Document) Japanese Patent Application Laid-Open No. Hei 6-315344

However, the treatment for alleviating the above symptoms is usually performed in a sitting position or in a standing position, and the temperature movement such as heating or cooling the affected part is not performed during bedtime or when the body is lying sideways, so that the body movements are not performed. This unpaid elderly person or sitting posture made them uncomfortable. Moreover, there was no means of alleviating the pain of the affected part while lying sideways.

In addition, although the degree of pain or coldness varies, hot compresses or the like could not be adjusted to the most optimal temperature for the degree of pain or coldness of each affected area. It is also used to carry people whose body temperature has exceeded 40 degrees, such as those who have fallen under heat stroke or burns, or those whose temperature has dropped rapidly, such as those who have a large amount of bleeding due to an accident. There is no such thing as an emergency medical device or a device in which the body temperature of the patient can be properly adjusted within the temperature range necessary for maintaining the body function while lying down. For example, a person who has a large amount of bleeding is covered with an electric blanket, but it is very difficult to properly adjust the patient with the electric blanket. In some cases, the patient may be disturbed, and the patient may be congested. In addition, as for medical supplies for senile hypothermia patients, there is no difficulty in appropriately adjusting the body temperature of the patient in a desired temperature range in a lying state, causing various difficulties.

For example, the body temperature of a patient in need of temperature adjustment, such as an emergency patient with a large amount of bleeding caused by a traffic accident or a sudden drop in body temperature, a patient who may suddenly change his or her condition in a hospital or clinic, or an elderly person at home. In order to properly adjust and prevent the above-mentioned defects, the body's situation (for example, body temperature, blood pressure, heart rate or the number of times the body is turned over during bedtime), for example, the heart rate monitor Accurately and continuously monitor using a blood pressure monitor etc., and based on the monitor data, for example, a caregiver must perform temperature adjustment of an electric blanket etc. sincerely. However, it is practically impossible for the caregiver to faithfully adjust the temperature of the electric blanket and the like by monitoring the physical condition accurately and continuously. In addition, conventionally, there has been no feedback means for continuously monitoring the physical condition in the lying state and automatically adjusting the temperature of the electric blanket or the like based on the monitor data.

Therefore, the applicant proposes the following temperature adjustment mat (not disclosed). The temperature adjusting mat circulates the temperature adjusted air in a sealed mat to adjust the temperature of the entire mat to provide a comfortable temperature environment to the body lying on the mat. As a specific structure, the mat body is composed of an airtight container with an outer skin such as artificial leather or a woven fabric, and inside the airtight container, a structure made of three-dimensional fibers or the like having high air flowability in order from the top is used to distribute the air. Mat material having an air circulation path is disposed at the passage wall for controlling and the bottom of the mat to form an air circulation path in the sealed container, and the air is circulated through the air circulation path to adjust the temperature of the circulation air. It is the structure which adjusts the whole temperature. However, the temperature adjustment mat of this proposal is mainly equipped with the structure which controls temperature of the wide part of the mat evenly for the sleep of a healthy person, and is an elderly person who does not have enough temperature adjustment detection and a control function, bleeding and a burn This did not meet the requirements of the temperature adjustment function in emergency medical care, such as local heating and cooling of a person who had lost body temperature function.

Patent Document 1 proposes a bed apparatus as described below. That is, the bed apparatus of patent document 1 is equipped with the sensor for detecting the body temperature, humidity, and body movement of a person in a bed, and the sensor is installed in the pad which was put on the mat of the bed apparatus separately. In addition, the bed apparatus is provided with a configuration for directly blowing air into the pad or bed on the mat by the blowing means, or a heating means for heating the blowing, and controlling the heating means based on the detected value detected by the sensor. The temperature and humidity in the bed are fed back to appropriate values, and the air not heated by passing through the pad from the bottom of the mat is blown onto the bed. Patent Document 1 discloses providing a duct inside a bed main body and providing a plurality of ventilation holes on a surface thereof.

However, in the bed apparatus of patent document 1, even if it tries to send wind directly in the pad or bed on a mat, since the exit of the wind is blocked by the body or the blanket on a bed, wind does not fall out well. For this reason, there is a drawback of low practicality in winter when using a thick blanket. In addition, when the pad is placed on the mat, the pad position is shifted by body movement such as torsion during bedtime, and there is a disadvantage that it is difficult to warm the desired position in detail. In addition, since the wind directly hits the body during bedtime and the body becomes excessively cold, there is a defect that is not necessarily necessary for the health of the elderly and the like in particular.

In addition, Patent Literature 1 discloses a configuration in which a cooling device using a Peltier effect is used as a means for lowering the needle bed temperature. However, in the case of cooling the outside air of high humidity in summer, there is a problem that dew occurs, and the mat itself is wet, so that mold is easily proliferated.

In addition, in the bed apparatus of Patent Document 1, the heating of the body is performed by a heater (heating means) on the mat. However, since the body temperature detecting means and the humidity detecting means are built in the pad disposed on the mat, the body temperature is precisely heated during heating. The problem of not being able to detect it well, the mat is filled with a lot of fiber as the inner cotton, and the heating means is generally heated to high heat capacity, so the power consumption is high, the heat of the heating means directly As a result of supplying to the whole body, there is a possibility that various problems may occur, such as a soreness of the body and, in severe cases, a low temperature burn.

This invention is made | formed in order to solve the said subject, The objective can adjust the temperature of the part of the body on a mat, and also does not cause problems, such as a soak and a low temperature burn, and the structure is simple and easy to use temperature adjustment To provide a mat.

MEANS TO SOLVE THE PROBLEM In order to achieve the said objective, this invention makes the structure shown next as a means for solving the said subject. That is, the present invention is a temperature adjusting mat having a function of adjusting the temperature of the body on the mat, wherein at least one partial temperature adjusting target area is predetermined on the surface of the body side of the mat, and the temperature adjusting target area. An air circulation passage for circulating air in the mat inner region of the mat to follow a portion of the mat skin of the temperature adjusting region, and at least a portion of the air circulation passage is formed of a highly breathable and highly breathable material. Air circulation means for forcibly circulating air in the air circulation passage and circulating air temperature adjustment for adjusting the temperature of the air circulating in the air circulation passage by adjusting the temperature of the body part on the temperature adjusting target region. Means and body temperature detecting means for detecting body temperature of the body part on the temperature adjusting target region and the body temperature detecting means And a control unit for controlling drive of the air circulation means and the circulating air temperature adjusting means such that the body temperature of the body part on the temperature adjusting target region becomes a predetermined target temperature based on the detection value of the means.

According to the present invention, at least one partial temperature adjustment region is set on the mat surface, and an air circulation passage for circulating air in the mat inner region of the temperature adjustment region, and forcibly introducing air to the air circulation passage. The air circulation means for circulating and the circulation air temperature adjusting means for adjusting the temperature of the circulating air are provided, and the temperature adjustment of the body part on the said temperature regulation target area | region is carried out by heat exchange with the temperature-regulated circulating air. It was set as the structure to perform. In this configuration, since the temperature adjusting region is a partial region of the mat surface, it is possible to adjust the temperature of a part of the body on the mat.

Further, for example, the heat of the heater is not directly supplied to the body on the mat, but in the present invention, since the temperature of the body on the mat is adjusted by using the temperature-regulated circulation air, the body soaks or cools on the mat. Problems such as an image can be avoided. In addition, the temperature adjusting mat of the invention can be constructed with a simple structure.

Further, in the present invention, the body temperature of the body portion on the temperature adjustment target region is set in advance to the target temperature based on the body temperature detecting means for detecting the body temperature of the body portion on the temperature adjustment target region on the mat surface and the detected value of the body temperature detection means. And a control unit for controlling the driving of the air circulation means and the circulating air temperature adjusting means. With such a configuration, it is possible to use a variety of products, such as those who are unable to control their temperature well with age, who are causing some physical abnormalities due to accidents, and who are disturbing their temperature control, or those who want healthy sleep. By setting the target temperature appropriately according to the physical condition or the needs of people, it is possible to provide a temperature adjusting mat that can efficiently adjust temperature to a desired part of the body.

In addition, a body state detecting means is provided, and the body temperature detecting means is provided so as to set the target temperature of the body part on the temperature adjustment target region on the mat surface in accordance with the body state detected by the body state detecting means. The target temperature is set, and the temperature adjustment of the body can be performed much more appropriately.

Further, external detection means for detecting ambient environment information, such as external temperature or humidity, is provided outside the mat, and the temperature adjustment target on the surface of the mat using ambient environment information detected by the external detection means. By having a configuration for setting the target temperature of the body part on the area, an appropriate target temperature is set in accordance with the change of the situation of the climate, and the temperature adjustment of the body can be performed much more appropriately. Further, both the body state detecting means and the external detecting means are provided so that the body part on the temperature adjustment target area on the mat surface is based on the body state detected by the body state detecting means and the ambient environment information detected by the external detecting means. By having a configuration for setting the target temperature of the target temperature, the target temperature is set in accordance with the situation of the climate and the body of each different body, it is possible to adjust the temperature of the body more appropriate.

A discharge port for discharging a part of the air in the mat is provided, and an air inlet for blowing external air into the mat is provided to compensate for the amount of air discharged, thereby exchanging a part of the air in the mat. can do. In addition, when the climate is warm, such as early autumn, and the heating or cooling due to the outside air is not necessary, the temperature inside the mat can be adjusted using the outside air, and the power consumption of the circulating air temperature adjusting means can be suppressed. Reduction can be achieved. Further, by providing a means for appropriately removing the humidity of the outside air blown into the mat at the air intake port, it is possible to blow the outside air into the mat without increasing the humidity in the mat.

In addition, since the circulating air temperature adjusting unit with the built-in circulating air temperature adjusting means is provided outside the mat, the circulating air temperature adjusting means can be easily repaired, repaired, and replaced.

Further, a plurality of temperature adjusting target areas are predetermined on the surface of the body side of the mat, and air circulation passages, air circulating means, and circulating air temperature adjusting means are provided for each temperature adjusting target area, respectively. By providing a configuration for driving control of the air circulation means and the circulating air temperature adjusting means for each adjustment target region, temperature adjustment can be performed separately for the body part on each temperature adjustment target region.

By having the structure in which the body temperature detecting means is provided as a member which can be mounted on the body part on the mat, it is possible to detect the body temperature of the body part on the temperature adjustment target region much more accurately.

In addition, by providing the affected portion treatment means for applying any one of heat, light and vibration to the body part on the mat surface portion of the non-air circulation region other than the temperature adjustment target region by air circulation, The effect as shown can be acquired. By attaching the wound treatment means to the inner part of the mat according to the purpose, for example, energy from the wound treatment means can be appropriately applied to a local body part (a wound) such as a shoulder or a foot to alleviate the symptoms of the wound. Moreover, when the control part is equipped with the structure which performs drive control of the affected part treatment means based on a control program given previously, the effect shown next can be acquired. For example, when a sweating sensor, which is a physical state detecting means, is provided, data for setting a target energy output amount from the affected area treatment unit in advance is provided based on the sweating amount detected by the sweating sensor. Sets a target energy output amount from the wound treatment means based on the information of the sweat amount detected by the sweat amount sensor and the data according to a control program given in advance, so that the amount of energy output from the wound treatment means is set to the target energy. The drive control of the affected area treatment means is carried out so as to output power. In this way, according to the change in the physical condition, it is possible to automatically apply the appropriate energy to the body part on the mat surface portion of the non-air circulation area to alleviate the symptoms of the affected part.

When at least one of the air circulation means, the circulating air temperature adjusting means, and the wound treatment means is provided and the manual operation means is manually operated, the control unit is configured to stop the automatic control and give priority to the manual operation. In response to other needs of the user, the temperature adjustment state of the body by the circulating air temperature adjusting means or the output energy supply state by the wound treatment means can be adjusted by manual operation.

(Example)

An embodiment of the present invention will be described below with reference to the drawings. In addition, the component in drawing used for description of the Example demonstrated below is not necessarily the same as the size.

1 is a perspective view showing a schematic appearance of the temperature adjusting mat of the first embodiment. The temperature adjusting mat 1 is provided with a function of sensing the body temperature of the body 65, adjusting the mat surface temperature, and adjusting the temperature of the body 65.

As shown in Fig. 1, the first temperature adjusting unit 2 and the second temperature adjusting unit 3, which are the temperature adjusting target regions, are set on the surface of the temperature adjusting mat 1 on which the body 65 is laid on its side. have. In the first embodiment, the first temperature adjusting unit 2 is set in a mat surface area corresponding to approximately the body 65. For example, in the summer, cooling of the back of the body 65 is performed in winter. Is an area for heating the body 65 and the like. Moreover, the 2nd temperature adjustment part 3 is set in the area | region corresponding to a leg part in the waist part of the body 65, The area | region which heats from the waist part to the leg part of the body 65 without cooling, to be.

In the first embodiment, a control unit for controlling air circulation means such as heat exchange means or blower fan, which is a circulating air temperature adjusting means described later, incorporated in the temperature adjusting mat 1 on the side of the temperature adjusting mat 1 ( 4) is installed.

2 is a cross-sectional view schematically showing an example of a cross-sectional configuration of the A-A portion of the temperature adjustment mat 1 shown in FIG. 1, and FIG. 3A is a schematic exploded view of the temperature adjustment mat 1 of FIG. 1. As shown in Fig. 2, the temperature adjusting mat 1 of the first embodiment includes an upper air flow unit 5 made of a highly breathable material, a lower air flow unit 6 made of urethane foam, and an upper air flow unit. (5) and a flow channel control means (7), an upper air flow means (5), a lower air flow means (6), and a flow channel control means, each comprising an aluminum plate or a woven fabric inserted into the lower air flow means (6). (7) the upper skin 11 and the lower skin 12 made of artificial leather, woven fabric, or the like wrapped with the laminated structure, the first heat exchange means 8 as circulating air temperature adjusting means, and the second as circulating air temperature adjusting means. It consists of a heat exchange means 9, a first air circulation means 10, a first temperature sensor 14, a second temperature sensor 15, and a second air circulation means 16. Below, the detail of each said component which comprises the temperature adjusting mat 1 is demonstrated.

The upper skin 11 and the lower skin 12, which are the skin of the temperature control mat 1, have low moisture permeability and air permeability, respectively, and have a thickness of, for example, about 0.5 to 2 mm, for example. It is composed of a fabric made of polyester, acrylic fiber or fluorine fiber, and has good cushioning property and can almost block air and external air inside the mat. The upper skin 11 and the lower skin 12 are made of the mat. It is sewn by sewing (縫製) to the extent that the flexibility is not impaired and consists of a bag shape. Since the upper skin 11 and the lower skin 12 almost block the air inside the mat and the outside air, moisture contained in the outside air penetrates into the mat, and condensation inside the temperature adjusting mat 1 is caused by cold air in the mat. I) can be prevented from occurring, and propagation of various germs due to excess moisture can be avoided.

In addition, although the inside of the temperature control mat 1 is comprised by the upper skin 11 and the lower skin 12 substantially airtight, the material of the upper skin 11 and the lower skin 12 is a fiber body fundamentally, When a body pressure of the temperature adjusting mat 1 is applied by the body 65, a part of the air inside the mat is discharged through the upper skin 11 or the lower skin 12 by the deformation of the mat. In addition, when the body 65 is raised on the mat (separation of the mat and the body), outside air flows into the mat through the upper skin 11 or the lower skin 12. When the inflow of the outside air into the mat, moisture penetrates to some extent through the upper skin 11 or the lower skin 12, so that the temperature adjusting mat 1 of the first embodiment to remove the humidity of the external air. The desiccant, such as a silica gel or zeolite, may be built in, and the ventilation means 54 for humidity control which consists of an electronic dryer etc. is provided in the mat periphery.

The upper air flow means 5 is a flat structure which extends along the upper surface of the temperature adjusting mat 1 and is made of a highly breathable material having good ventilation and low heat capacity and good cushioning property. An embodiment of this upper air distribution means 5 is shown in the model diagram of FIG. 4. The upper air distribution means 5 shown in FIG. 4 is a three-dimensional fiber structure having a thickness of, for example, about 10 to 30 mm, and a cotton-like fabric part (lattice-like fiber) that is a cloth structure of two outer and inner layers. ) And a connecting means 20 made of a fiber connecting the upper and lower face-shaped fabric portions 19.

The cotton fabric portion 19 is a fabric having good air permeability in the up and down direction (b direction in FIG. 4) and having a high porosity (opening) per unit area of about 70 to 80%, for example, as a multi filament. Polyester fibers such as polyethylene terephthalate (PET) and polybutylene terephthalate (PBT), and polyamide fibers such as nylon 6 and nylon 66. Since this cotton fabric part 19 has good air permeability, air can be easily distribute | circulated in the up-down direction (b direction of FIG. 4) through the said cotton fabric part 19. FIG.

The connecting means 20 is woven integrally with the cotton fabric portion 19 and is three-dimensionally formed by heat treatment. The connecting means 20 has a high porosity in the cross section orthogonal to the face of the cotton fabric portion 19, for example, about 80 to 95%, and in the in-plane direction (a direction in FIG. 4). Air is going to flow easily. Since the connecting means 20 receives the body 65 lying on the upper part of the temperature control mat 1 by a moderate degree of compression deformation through the upper skin 11, it is composed of a strong thread that recovers even if repeated compression torsion occurs. have. As a specific example of this yarn, a plurality of rigid monofilament fibers made of, for example, polyethylene terephthalate or polybutylene terephthalate having a thickness of about 600 to 800 denier are somewhat curved and arranged. Or a plurality of monofilament fiber bodies arranged so as to have an X shape.

As described above, the upper air flow means 5 of FIG. 4 is a collection of fine fibers, and the porosity is high, so that the weight per unit volume of the upper air flow means 5 is when the unit volume is filled with solids. The heat capacity of the upper air flow means 5 is extremely low, and the thermal conductivity in the vertical direction (b direction) is also low. Therefore, the heat of the body 65 lying on the upper part of the temperature adjusting mat 1 can be prevented from accumulating in the upper air distribution means 5.

The flow path control means 7 is constituted by an aluminum plate, a woven fabric, or the like, and the flow path control means 7 includes a plurality of through holes 17 penetrating in the vertical direction, for example, as shown in FIG. 3A. (17a to 17d)) are formed. The through hole 17a, which is one of the plurality of through holes 17, is formed at a portion corresponding to a part of the edge of the first temperature adjusting part 2, and the edge of the first temperature adjusting part 2 is formed. Another through hole 17b is formed corresponding to the short edge on the opposite side of the portion. Moreover, the other through hole 17c is further formed in the site | part corresponding to a part of the edge part of the 2nd temperature adjustment part 3, and the other through hole corresponding to the edge part on the opposite side of the edge part of the 2nd temperature adjustment part 3 is different. 17d is formed.

The lower air distribution means 6 is comprised by the member of the flat shape which consists of urethane foam etc., for example. FIG. 3B shows a schematic plan view of the lower air flow means 6 seen from above. As shown in FIG. 3B or FIG. 2, recesses 18-1, 18-2, and 21 are formed on the upper surface of the lower air flow means 6 (the side of the upper air flow means 5). The recessed part 21 is for providing the 1st heat exchange means 8, and is provided corresponding to the formation position of the through-hole 17a of the flow path control means 7. As shown in FIG. The recessed part 18-1 is formed over the area | region which communicates with the recessed part 21 in the part corresponding to the formation position of the through hole 17b of the flow path control means 7, and forms an air circulation path as mentioned later. It is for. The recessed part 18-2 is formed over the part corresponding to the formation position of the through hole 17d of the flow path control means 7 in the part corresponding to the formation position of the through hole 17c of the flow path control means 7, which will be described later. It is for forming an air circulation passage as shown.

The first air circulation means 10 is constituted by a blowing fan such as a cross flow fan. In the first embodiment, as illustrated in FIG. 2, the flow path control means 7 is illustrated. Is formed in the formation area of the through hole 17a. The second air circulation means 16 is also constituted by a blowing fan such as a cross flow fan, similarly to the first air circulation means 10. In the first embodiment, the second air circulation means 16 is arranged in the formation area of the through hole 17c of the channel control means 7.

In the first embodiment, by driving the first air circulation means 10, for example, the air inside the upper air flow means 5 is sucked by the first air circulation means 10. The sucked air is discharged from the first air circulation means 10 toward the recessed portion 18-1 of the lower air flow means 6, and passes through the passage consisting of the recessed portion 18-1 and the channel control means 7. Then, it passes back through the through hole 17b of the flow path control means 7 and returns to the upper air flow means 5. The returned air passes through a portion of the upper air flow means 5 corresponding to the first temperature adjuster 2 and is again sucked by the first air circulation means 10. As described above, by the driving of the first air circulation means 10, the circulation of air as indicated by arrow A in FIG. 2 occurs in the mat inner region corresponding to the first temperature adjusting part 2. The circulating air exchanges heat with the part of the body 65 (for example, the back) which is in contact with the first temperature adjusting part 2 through the upper skin 11 while passing through the upper air flow means 5. .

That is, inside the mat corresponding to the first temperature adjusting part 2 by the upper air flow means 5, the through holes 17a, 17b of the flow path control means 7, and the recess 18-1 of the lower flow means 6; A first air circulation passage for circulating air into the region is configured. In addition, the first air circulation means 10 is composed of air circulation means for forcibly circulating air in the first air circulation passage.

In addition, by driving the second air circulation means 16, for example, the air in the air circulation passage composed of the recessed portion 18-2 of the lower air flow means 6 and the flow passage control means 7 receives the second air circulation. Drawn by means 16. The sucked air is discharged toward the area of the upper air flow means 5 corresponding to the second temperature control portion 3, and the area of the upper air flow means 5 corresponding to the second temperature adjust portion 3. After passing through the through hole 17d of the flow passage control means 7, it returns to the recessed portion 18-2 of the lower air flow means 6. This returned air passes through the recessed portion 18-2 and is again sucked by the second air circulation means 16. In this way, the circulation of air as shown by arrow B in FIG. 2 occurs in the mat inner region corresponding to the second temperature adjusting section 3 by the driving of the second air circulation means 16. The circulating air passes through the upper air flow means 5 and extends through the upper skin 11 to the portion of the body 65 (eg, from the waist to the leg) that is in contact with the second temperature adjusting portion 3. Heat exchange with body parts).

That is, inside the mat corresponding to the second temperature adjusting part 3 by the upper air flow means 5, the through holes 17c, 17d of the flow path control means 7, and the recessed part 18-2 of the lower flow means 6; A second air circulation path for circulating air in the area is configured. The second air circulation means 16 is an air circulation means for forcibly circulating air in the second air circulation passage.

In the first embodiment, since the upper air flow means 5 has good ventilation, for example, when the thickness of the upper air flow means 5 is 30 mm, the first and second air circulation means 10 and 16 are used. The wind speed in the upper air distribution means 5 of the circulating air by driving of is 0.5-2 (m / sec), for example, and the air volume is large, for example, 0.1-0.5 (m3 / sec). Air circulation of wind speed and big wind volume can be obtained. In addition, since the upper air distribution means 5 shown in FIG. 4 has a three-dimensional connection means 20, it flows from the through-hole 17 of the channel control means 7 to the upper air distribution means 5. Since the incoming air becomes turbulent to impinge on the connecting means 20 of the upper air flow means 5 and collides with the upper skin 11, heat exchange with the body 65 can be efficiently performed, for example, 5 minutes. The temperature adjustment of the comfortable body 65 can be obtained between the degrees.

The first heat exchange means 8 is for adjusting the temperature of the air circulating in the first air circulation passage A. In the first embodiment, the first heat exchange means 8 is attached to the recess 21 of the lower air flow means 6. have. 5A is a schematic perspective view showing an example of the configuration of the first heat exchange means 8. The first heat exchange means 8 of FIG. 5A is composed of a Peltier module 22 as described below and a temperature adjusting pin 23 made of aluminum or the like connected to the Peltier module 22.

The Peltier module 22 is a kind of heat pump for transferring heat from one side of the module to the other side using the Peltier effect and is widely used as a temperature control device for a small refrigerator or an electronic component. The Peltier module includes a matrix arrangement composed of alternating n-type semiconductor elements and p-type semiconductor elements as main components, ceramic substrates such as alumina and the like, which are arranged to be inserted in the vertical direction, and It is provided in each upper and lower ceramic substrate, and is comprised from the upper electrode group and lower electrode group which electrically connect an n-type semiconductor element and a p-type semiconductor element. The number of pairs of n-type semiconductor elements and p-type semiconductor elements required for the Peltier module is usually 100 to 300 pairs, depending on the necessary temperature adjusting ability (heat absorption amount and temperature difference). The type semiconductor element is electrically connected in series alternately by the upper electrode group and the lower electrode group. When a direct current is applied to the series connection body of the n-type semiconductor element and the p-type semiconductor element, one side of the Peltier module 22 becomes the cooling surface (heat absorbing surface), and the other side facing the heating surface (array surface ) 面)). Inverting the flow of direct current flowing through the series connection of the n-type semiconductor element and the p-type semiconductor element causes one side of the Peltier module 22 to change from the cooling side (heat absorption side) to the heating side (array side), The opposite side changes from the heating side (array side) to the cooling side (endothermic side). For this reason, there is a merit that the Peltier module 22 can perform both cooling and heating only by the Peltier module 22.

The temperature adjusting pin 23 is attached to one side of the Peltier module 22 and is cooled or heated by the driving of the Peltier module 22. In the first embodiment, the positional relationship between the temperature adjusting pin 23 and the first air circulation means 10 is set such that the circulating air discharged from the first air circulation means 10 passes through the temperature adjustment pin 23. It is. For this reason, the circulating air discharged from the first air circulation means 10 passes through the temperature adjusting pin 23 to be heat exchanged to cool or heat.

By the way, in the case where the first heat exchange means 8 is constituted by the Peltier module 22, the arrangement generated when the Peltier module 22 performs the cooling operation of the circulating air is carried out. It is preferable to discharge to the outside. For this reason, as shown in FIG. 5A, the Peltier module 22 is attached to the heat transfer means 25. A part of the heat transfer means 25 is formed to protrude to the outside of the temperature adjusting mat 1, and the portion of the heat transfer means 25 which protrudes is arranged on the side surface of the temperature adjusting mat 1 ( It is joined with 24).

The heat transfer means 25 has a configuration that can efficiently transfer the arrangement of the Peltier module 22 to the arrangement means 24, such a configuration, for example, there are various configurations such as a heat pipe or a heat pipe panel, Here, any of those configurations may be adopted. 5B is a schematic sectional view of an example of the configuration of the heat transfer means 25. The heat transfer means 25 of FIG. 5B is constituted by a heat pipe panel 68. In the heat pipe panel 68, a plurality of through holes 67 are formed in the outer portion 66, for example, made of aluminum having a thickness of about 2 mm and a width of about 30 mm. Each has a structure in which working fluid (for example, water, a replacement flon, etc.) is accommodated.

The arranging means 24 includes, for example, an arranging pin 27 composed of a plurality of aluminum plates or copper plates thermally bonded to the heat transfer means 25 by soldering or the like, and ventilating the arranging pins 27. A cover formed of, for example, an array fan 26 made of, for example, an axial fan for supplying, and a plastic, aluminum, or the like for efficiently guiding the ventilation by the array fan 26 to the array pin 27. Crisis (28).

By installing the heat transfer means 25 and the arrangement means 24 as described above, the arrangement of the Peltier module 22 is transferred to the arrangement means 24 through the heat transfer means 25, and the external air is arranged by the arrangement means 24. Heat exchanged with. That is, the arrangement of the Peltier module 22 can be discharged to the outside of the temperature control mat 1.

The second heat exchange means 9 is for adjusting the temperature of the air circulating in the second air circulation passage B. In the first embodiment, the second heat exchange means 9 is disposed in the formation area of the through hole 17d of the flow channel control means 7. have. In the first embodiment, the second heat exchange means 9 is constituted by, for example, a heater or a Peltier module as described above for heating the circulating air.

In the first embodiment, the first heat exchange means 8 is arranged in the first air circulation passage A as described above. For this reason, the air circulating in the first air circulation passage A is temperature-controlled by the first heat exchange means 8, and the temperature-controlled air corresponds to the upper air flow means (corresponding to the first temperature adjusting section 2). 5) through the site, and by heat exchange through the upper skin 11 between the temperature-regulated circulating air and the site of the body 65 (eg, etc.) in contact with the first temperature control section 2, The part of the back of the body 65 can be cooled or heated. In addition, the second heat exchange means 9 is arranged in the second air circulation passage B. For this reason, the air circulating in the second air circulation passage B is temperature-controlled by the second heat exchange means 9, and the temperature-controlled air corresponds to the upper air flow means (corresponding to the second temperature adjusting section 3). 5) the upper epidermis 11 between the body temperature 65 (eg, the region extending from the waist to the leg) in contact with the temperature-controlled circulating air and the second temperature adjusting section 3 because it passes. The body 65 portion can be heated by heat exchange through the body.

The 1st temperature sensor 14 detects the mat surface temperature of the 1st temperature control part 2 by the body temperature of the part of the body 65 which contact | connects the 1st temperature control part 2, and the 2nd temperature sensor 15 is The mat surface temperature of the 2nd temperature adjusting part 3 is detected by the body temperature of the part of the body 65 which is in contact with the 2nd temperature adjusting part 3. Each of the first and second temperature sensors 14 and 15 receives, for example, temperature sensors such as a plurality of small diameter thermoelectric pairs or infrared rays emitted from the body, and is based on the wavelengths of the received infrared rays. It is comprised by the photodiode PD etc. which detect a temperature. In the first embodiment, the first temperature sensor 14 is arranged in three positions 30-1, 30-2 and 30-3 of the first temperature adjusting unit 2 as shown in Fig. 3A. Moreover, the 2nd temperature sensor 15 is arrange | positioned in three places of the position 31-1, 31-2, 31-3 of the 2nd temperature control part 3 as shown to FIG. 3A, respectively.

The control unit 4 is comprised of the control part 32 shown in the block diagram of FIG. 8, the temperature data processing parts 33 and 34, and the memory 38. As shown in FIG. The body temperature data processing unit 33 is electrically connected to three first temperature sensors 14 (30-1, 30-2, 30-3) provided in the first temperature adjusting unit 2, respectively. The body temperature data of the body 65 detected by the first temperature sensor 14 is received at all times, and the received body temperature data is processed. In the first embodiment, the body temperature data processing unit 33 compares the detection temperatures of the three first temperature sensors 14 and sets the highest temperature among the detected temperatures to the body 65 in the first temperature adjustment unit 2. It is regarded as the body temperature of the ()) and has a configuration to output to the control unit 32. For example, in FIG. 7A, data of detection temperatures output from three first temperature sensors 14 (30-1, 30-2, and 30-3) installed in the first temperature adjusting unit 2 are shown. . When the detection temperature data as shown in FIG. 7A is obtained, the highest detection temperature is the detection temperature (32 ° C.) of the first temperature sensor 14 (30-3). The body temperature of the body 65 is detected at 32 ° C. In this way, the highest temperature among the detected temperatures of the three first temperature sensors 14 is regarded as the body temperature of the body 65. The body 65 is moved on the temperature adjusting mat 1 by the body's movement such as overturning. Since not all the first temperature sensors 14 detect the body temperature of the body 65, the body 65 detects the highest detection temperature that is thought to sense the heat from the body 65 with the highest accuracy. ) Is at body temperature.

The body temperature data processing unit 34 is electrically connected to three second temperature sensors 15 (31-1, 31-2, 31-3) provided in the second temperature adjusting unit 3, respectively. The body temperature data of the body 65 detected by each second temperature sensor 15 is received at all times, and the received body temperature data is processed. In the first embodiment, the body temperature data processor 34 compares the detected temperatures of the three second temperature sensors 15 in the same manner as the body temperature data processor 33 and sets the highest temperature among the detected temperatures to the second temperature adjuster. It is regarded as the body temperature of the body 65 in (3), and it outputs to the control part 32.

In the memory 38, the relationship data between the time and target temperature (target body temperature) as shown by the solid line A in Fig. 7B is predetermined and stored as target temperature data. The control part 32 is comprised by the microcomputer (CPU), for example, The said control part 32 is the body temperature output from the data, the program, and the temperature data processing parts 33 and 34 stored in the memory 38. Drive control of each of the first and second heat exchange means 8 and 9, the first and second air circulation means 10 and 16 and the like is performed based on the information and the like. For example, the control part 32 has time measurement means, sets the target temperature according to the time information obtained by this time measurement means to each hour based on the target temperature data of the memory 38, and sets this target The body temperature data added from the temperature and the body temperature data 33 and 34 are compared. And the control part 32 controls the power supply part 35 in the direction which makes the said difference small based on the difference between the detected body temperature and the target temperature obtained by the comparison, and the 1st and 2nd heat exchange means 8 and 9 respectively. Drive control and drive control of the first and second air circulation means (10, 16).

And the target temperature data A shown in FIG. 7B is data used for making a person sleep easily, for example, when a healthy person cannot fall asleep. In other words, the human body generally lowers the set point of the body temperature at night and lowers the metabolic rate by lowering the body temperature by 0.5 ~ 1 ℃ before going to sleep at night. For this reason, as can be seen in the warming of the limbs of a child before going to sleep, the blood vessels on the skin surface are expanded to increase heat dissipation from the skin surface. Therefore, in order to shorten the time to sleep, it is necessary to lower the temperature of the temperature adjusting mat 1 in accordance with the heat dissipation of the body so that the heat dissipation from the body can be easily performed, but the temperature of the mat is set low from the beginning. In this case, the cold stimulus is transmitted to the brain and the peripheral nerves are also contracted to suppress the release of body temperature. Therefore, the surface temperature of the temperature adjusting mat is once warmed, and the skin temperature on the surface of the body begins to deprive the acid heat. I can sleep well. In addition, even after sleep, a pattern such as V-shaped sleep, which is controlled at an appropriate temperature, for example, after cooling for the first time and gradually becomes a temperature equal to room temperature can be taken. In consideration of the above, the target temperature data A shown in FIG. 7B is set. That is, the target temperature data A is set in the starter (atmosphere) so that the mat surface temperature is adjusted (heated) to a temperature that does not give a cold stimulus to the sleeper and waits for the body 65 to lie down. Then, when the body 65 is lying on the upper part of the temperature adjusting mat 1, heating of an appropriate constant temperature is performed between about 10 to 30 minutes (heater in the middle), and the skin temperature of the body 65 is increased. The target temperature data A is set so that the body temperature and the skin temperature of the body 65 are lowered to enter the water surface when starting to go.

In addition, in this example, although the target temperature data A was for introducing a healthy person into comfortable sleep, for example, when using the temperature adjustment mat 1 as a mat for first aid, a memory ( 38), the first temperature and first temperature targets for first aid for low body temperature are given, and the control section 32 is based on the first temperature and first temperature based on the first temperature target temperature data for first aid and the body temperature detected by the body temperature data processing units 33 and 34. It is good also as a structure which performs drive control of each heat exchange means 8 and 9 and the 1st and 2nd air circulation means 10 and 16. FIG. Thus, the target temperature data is not limited to the data shown in FIG. 7B. In addition, of course, the target temperature data for the first temperature adjusting unit 2 and the target temperature data for the second temperature adjusting unit 3 are set, respectively, and the controller 32 controls the first heat exchange for the first temperature adjusting unit 2. The drive control of the means 8 and the first air circulation means 10 and the drive control of the second heat exchange means 9 and the second air circulation means 16 for the second temperature adjusting unit 3 are independently performed. You may also In addition, a plurality of target temperature data are stored in advance in the memory 38, and the user or the like of the temperature adjusting mat 1 is connected to the control unit 4, for example, by external information input means such as a keyboard or a touch panel ( Using a plurality of target temperature data in the memory 38, the controller 32 selects a desired one, and the controller 32 controls the first and second angles based on the selected target temperature data. It is good also as a structure which performs drive control of the heat exchange means 8 and 9 and the 1st and 2nd air circulation means 10 and 16. FIG. In addition, the control unit 32 uses external information input means by a user of the temperature adjusting mat 1 and the like, and uses the first and second heat exchange means 8 and 9 or the first heat exchange means using data of the target temperature input externally. You may be provided with the structure which performs drive control of the 1st and 2nd air circulation means 10 and 16. FIG.

In addition, the outside air temperature sensor 36 which is an external detection means is arrange | positioned outside the temperature adjusting mat 1, and the target is based on the outside air temperature (ambient environment information) detected by the outside air temperature sensor 36 in the memory 38. The correction data for correcting (setting) the temperature data may be stored in advance. In this case, the control unit 32 corrects (sets) the target temperature data on the basis of the information of the outside temperature detected by the outside temperature sensor 36 and the data for correction of the memory 38, and after this correction (after setting) The target temperature may be set based on the target temperature data, and the drive control of the first and second heat exchange means 8 and 9 or the first and second air circulation means 10 and 16 may be performed.

By appropriately providing the above-described various configurations, the control unit 32 controls the specific portion of the body 65 on the temperature adjusting mat 1 according to the change of the surrounding environment such as climate, the purpose of use of the temperature adjusting mat 1, and the like. The temperature can be adjusted to a constant temperature or to a temperature based on a set temperature pattern as time passes.

Further, manual operation means for circulating air temperature adjusting means for manually operating the first heat exchange means 8, manual operation means for circulating air temperature adjusting means for manually operating the second heat exchange means 9, and first At least one of the manual operation means for the air circulation means for the manual operation of the air circulation means 10, and the manual operation means for the air circulation means for the manual operation of the second air circulation means 16, the temperature adjusting mat (1) It may be installed in. In this case, the control unit 32 is the first heat exchange means 8 or the second heat exchange means 9 or the first air circulation means 10 or the second air when the manual operation means is manually operated. Automatic control of the circulation means 16 is stopped to give priority to manual operation. By having such a configuration, for example, when the temperature adjusting mat 1 is used for therapeutic purposes under the supervision of a doctor, the first and second respective heat exchange means from the medical point of view on the basis of body temperature data and the like ( 8 and 9 or the first and second air circulation means 10 and 16 can be manually operated to adjust the temperature of the body 65 on the temperature adjusting mat 1.

In addition, the control unit 32 is connected to the wireless or wired communication means 39, and transmits predetermined temperature information such as body temperature information obtained through the body temperature data processing units 33 and 34, data stored in the memory 38, and the like. Communicating to the other party (e.g., when the temperature adjusting mat 1 is installed in a nursing facility or hospital, or a centralized data processing device of the facility, or a hospital where the patient is returned if an ambulance is installed). You may have a structure.

The control unit 32 may be connected to the monitor device 37 and control the monitor device 37 to display the body temperature information and the like obtained through the body temperature data processing units 33 and 34.

In addition, although the example which performs heating and cooling of the circulating air of the Peltier module 22 which comprises the 1st heat exchange means 8 was shown in this 1st Example, the Peltier module 22 is cooled, for example. For the purpose of exclusive use, the first heat exchange means 8 may be provided with a heating means different from the Peltier module 22. That is, in general, when the Peltier module is used to heat the Peltier module, it is easy to deteriorate at high temperature, and when the Peltier module is used in the heating mode, the array pin 27 must be warmed, so that the heater for warming the array pin 27 is used. This results in an increase in the number of parts and complexity of the structure, such as the need to be provided at the array pin 27, so that heating of the circulating air by the Peltier module is not preferable. In consideration of this point, the Peltier module 22 may be dedicated to cooling the circulating air, and a means for heating the circulating air may be separately provided. For example, as shown in FIG. 6, you may provide the surface heater 29 as a heating means of circulation air on the upper surface of the temperature adjusting pin 23. As shown in FIG. The planar heater 29 is formed by embedding a heating element in an insulating sheet made of a silicone resin, polyimide, or the like having a thickness of about 0.2 to 0.5 mm, for example. In the case of providing the heater 29 in the form of a plane, as shown in FIG. 6, the heat of the heater 29 in the plane does not radiate heat to the outside and is efficiently supplied to the temperature adjusting pin 23 side. It is preferable to provide a heat insulating material 30 such as polyurethane foam on the heater 29.

In addition, in the first embodiment, the heat exchange means 8 is composed of a Peltier module 22, but the heat exchange means 8 replaces the Peltier module 22 with heating means such as a heater and cooling means. It is good also as a structure.

A second embodiment will be described below. In the description of the second embodiment, the same components as in the first embodiment will be denoted by the same reference numerals, and the description of the common portions will be omitted.

In the second embodiment, the second temperature sensor 15 is used instead of the second temperature sensor 15 for detecting the body temperature of the body part located on the second temperature adjusting part 3 on the mat surface. 15 is provided as a member which can be attached to the body 65, as shown to FIG. 9A. The configuration of the second embodiment other than this configuration is the same as that of the first embodiment.

The temperature adjusting mat 1 shown in this second embodiment is very suitable for use for lifesaving of an elderly person whose body temperature adjusting function due to a sudden change in an emergency stretcher, an emergency bed or an outdoor environment is used, for example. For example, when an injury accompanied by bleeding due to a traffic accident or the like causes a rapid decrease in body temperature, in general, when the body temperature drops below 25 ° C, death often occurs. In addition, it is sometimes seen that some elderly people have a low body temperature and die due to a malfunction of the skin's hot and cold organs. In such a case, for example, as shown below, the relationship data between time and target temperature is stored in advance in the memory 38 as target temperature data. For example, the target temperature data includes hypothermic patients (e.g., patients whose skin temperature cannot be maintained at 32-33 ° C, which is the skin temperature of normal people) 65 at the beginning of the temperature adjustment mat 1. Since warming is urgently needed, the target temperature is set to 36 ° C, for example. However, if the surface temperature of the temperature adjusting mat 1 is kept at a high temperature for too long, it adversely affects the skin of the patient 65, so that if the body temperature of the patient 65 starts to rise gradually in advance, The target temperature is set, for example, by lowering to 32 ° C at the time when the predetermined time elapses.

The temperature is controlled by driving control of the first and second air circulation means 10 and 16 or the first and second heat exchange means 8 and 9 by the controller 32 using the target temperature data in the memory 38. The body temperature of the hypothermic patient 65 lying on the adjustment mat 1 can be raised to an appropriate body temperature.

For example, when the patient 65, which has become low in temperature due to a large amount of bleeding in the leg by an accident, is laid down on the temperature adjusting mat 1 of the second embodiment and temperature-controlled, the second temperature sensor 15 An example of the time change between the detected body surface temperature and the surface temperature of the temperature adjusting mat 1 is shown in the graph of FIG. 9B. In the example of FIG. 9B, the patient was in a dangerous state such as, for example, 26.5 ° C., but the body temperature can be gradually raised appropriately gradually by heating the temperature adjusting mat 1. And in the example of FIG. 9B, the target temperature is set to fall to 36 degreeC from 36 degreeC, for example at the time of transition to a suitable state from a high temperature holder.

In addition, although the target temperature data for raising the body temperature of the patient 65 of low body temperature was shown in this 2nd Example, of course, even in the temperature adjustment mat 1 of this 2nd Example, the target temperature data is a hypothermic patient. For example, the target temperature data for quenching the patient may be provided in order to cope with burn patients, and the target may be a body temperature for lowering blood pressure by expanding blood vessels in order to cope with a patient such as hypertension. You may set temperature data. Of course, when the body temperature of the patient 65 lying on the temperature adjusting mat 1 must be increased, an electric blanket or the like may be used in combination, and in this case as well, the body temperature of the patient can be appropriately increased. In addition, when the body temperature of the patient 65 on the temperature adjusting mat 1 must be cooled, a coolant or the like may be used in combination. In this case, the body temperature of the patient can be appropriately cooled.

A third embodiment will be described below. In the description of the third embodiment, the same reference numerals are given to the same constituent parts as the first and second embodiments, and the overlapping description of the common parts is omitted.

In this third embodiment, the first temperature adjusting part 2 and the second temperature adjusting part 3 as shown in FIG. 10 are set on the surface of the body side of the temperature adjusting mat 1 as the temperature adjusting target area, respectively. In this third embodiment, the mat inner region of the second temperature adjusting unit 3 is an air circulation region which is temperature-controlled using air circulation, and the mat inner region of the first temperature adjusting unit 2 is a non-air circulation region. It is. In the third embodiment, the first and second temperature adjusting units 2 and 3 are narrower than the temperature adjusting units 2 and 3 shown in the first and second embodiments. The temperature adjusting mat 1 is low in power consumption required for temperature adjustment of the body parts on the first and second temperature adjusting units 2 and 3.

As shown in the schematic cross-sectional view of FIG. 11, the temperature adjusting mat 1 of this third embodiment has the unit accommodating portion 40 and the upper air communicating means 5 arranged on the upper side of the unit accommodating portion 40. ) And an upper skin 11 and a lower skin 12, which are the skin covering the stack of the unit accommodating portion 40 and the upper air flow means 5.

The upper air distribution means 5, the upper skin 11 and the lower skin 12 are the upper air distribution means 5, the upper skin 11 and the lower skin 12 shown in the first and second embodiments, respectively. ) Has the same configuration. The unit accommodating part 40 is comprised by heat insulating materials, such as a polyethylene foam, The unit accommodating part 40 has the position corresponding to the 1st temperature adjusting part 2, and the position corresponding to the 2nd temperature adjusting part 3. 11, recessed part 40a, 40b is formed in each. In the recess 40a corresponding to the first temperature adjusting part 2, a temperature adjusting unit 41-1 as described later for adjusting the temperature of the first temperature adjusting part 2 is inserted. It is fixed by fixing means (not shown), such as a screw. Moreover, the temperature adjusting unit 41-2 is inserted in the recessed part 40b corresponding to the 2nd temperature adjusting part 3 so that temperature adjustment of the 2nd temperature adjusting part 3 may be performed later, It is fixed by fixing means (not shown), such as an adhesive agent and a screw.

12A is a simplified exploded view of the temperature adjusting unit 41-1, and FIG. 12B is a schematic cross-sectional view of the temperature adjusting unit 41-1. The temperature regulating unit 41-1 includes heat insulating means 43 disposed on the bottom surface of the recess 44a and the recess 44a formed in the envelope 44 and the heat insulating means ( 43 is stacked on the upper side, and the heating means (for example, the heater) 46 and the heat insulating means 43 and the heating means 46 accommodated in the recess 44a of the enclosure 44 are accommodated. It is comprised by the cover means 45 which closes the opening part of the recessed part 44a of the outer enclosure 44. In addition, although the lead wire etc. for supplying electric power of a power supply are provided in the heating means 46, illustration of a lead wire etc. is abbreviate | omitted in FIGS. 12A and 12B.

The outer enclosure 44 constituting the temperature adjusting unit 41-1 is made of, for example, a metal material having a low thermal conductivity such as stainless steel. The cover means 45 is made of a material having a high far-infrared transmittance such as zinc sulfide, a mesh made of metal or a fluorine resin, or the like, and prevents the heating means 46 from directly contacting the upper air flow means 5. It is to.

In this third embodiment, the heating means 46 is a wound treatment means for applying heat (light) energy to the body part on the mat surface portion on the non-air circulation region, and is constituted by a far infrared heater. It is typical sectional drawing of one structural example of a far infrared heater. In the example of FIG. 13A, the heating means 46, which is a far infrared heater, is formed of a foil made of a nickel alloy having a thickness of about 50 to 100 μm in a heat resistant insulator 48 made of polyimide having a thickness of about 0.2 to 0.4 mm. The porous far-infrared radiation material 53 having a thickness of about 100 μm is applied onto a planar heater in which the heat generator 47 is embedded. Far-infrared radiation material is a wavelength region of 8 to 10㎛, which has high absorption effect on the skin of the body, and a material capable of efficiently emitting far-infrared rays even at low temperature below 100 ° C, for example, cordierite (2MgO · 2Al). ₂ O _3, 5SiO _2, preferably using a material, such as Cordierite) or β sports dyumen _{(Li 2 O · Al 2 O} 3 · 4SiO 2, Spodumene). In addition, as a far-infrared radiation source, a material having high far-infrared radiation performance such as carbon cloth or cordierite as a solution or powder, and attaching to the surface of the fiber material to cover the surface of the fiber material You may employ | adopt as a material.

The heat insulating means 43 is for preventing the heat generated from the heating means 46 from being transferred to the enclosure 44 for use. For example, a sintered hollow glass sphere having a diameter of about 10 μm or pearlite is used. It consists of shape | molding ceramics with low thermal conductivity, such as (perlite), in plate shape about 5 mm in thickness. Further, in order to insulate the heating means 46 and the bottom surface of the recess of the enclosure 44 more effectively, the heating means 46 is not brought into surface contact with the heat insulating means 43, for example, the heating means. It is good also as a structure which makes point 46 contact the heat insulation means 43 in several places. Further, an infrared reflecting means may be provided by depositing aluminum foil or the like on the surface of the heat insulating means 43 on the heating means 46 side.

The temperature adjusting unit 41-1 shown in FIG. 12A is comprised as mentioned above, This temperature adjusting unit 41-1 is attached to the recessed part 40a of the unit accommodating part 40, and is shown in FIG. The temperature of the first temperature adjusting unit 2 may be increased by the radiant heat of the heating means 46. In addition, the far-infrared ray has extremely high light absorptivity at 1, so that the radiation effect is high even if the heating temperature of the heating means 46 is about 50 ° C. In addition, since the temperature adjusting unit 41-1 heats the first temperature adjusting unit 2 by radiant heat, the air circulation is not necessarily required, but the upper air distribution means 5 is used to reduce the discomfort caused by local heating. You may be provided with the structure which circulates air in the inside.

In this third embodiment, the first temperature adjusting unit 2 is provided with a humidity sensor 49 which is a physical state detecting means as shown in Fig. 12B. The humidity sensor 49 detects the amount of moisture, such as sweat, secreted from the covering surface of the body 65 in the amount of sweating. There are various types of humidity sensors, and any type of humidity sensor may be employed as the humidity sensor 49, but an example thereof is a capacitive polymer sensor that is a humidity sensor. The capacitive polymer sensor is formed by depositing metals such as gold on both surfaces of a polymer film having high hygroscopicity such as cellulose acetate or polyvinyl alcohol, and having electrode lead wires formed on both sides thereof. It is a sensor that detects humidity by changing the capacitance between the upper and lower metal films of the polymer film. For example, as a capacitive polymer sensor, there is a mini cap 2 made by Panamatrix, Japan.

In the example shown in FIG. 12B, the humidity sensor 49 is housed inside the sensor housing 50. The sensor housing 50 is made of a relatively coarse fabric made of a breathable, high moisture permeable material, for example, cotton fiber, for example, and preferably has a bag shape or a box shape extending from a bag shape or a pillow. Do.

In this third embodiment, the control unit 32 is predetermined and accepts the humidity information (perspiration information) output from the humidity sensor 49 at a time according to the control program stored in the memory 38 at all times. The drive control of the heating means 46 of the temperature adjusting unit 41-1 is performed so that the amount of water disposed from the body 65 is equal to or less than a predetermined set value based on the humidity information. In addition, a manual operation means for affected part treatment means for manually operating the heating means 46 may be provided. When the manual operation means for affected part treatment means is provided, the control unit 32 is a manual operation means for affected part treatment means. When the manual operation is detected, the automatic control of the heating means 46 may be stopped to prioritize the manual operation by the manual operation means for the wound treatment means.

14A is a schematic exploded view of the temperature adjusting unit 41-2, and FIG. 14B is a schematic cross-sectional view of the temperature adjusting unit 41-2. The temperature adjusting unit 41-2 includes the block body 51, the unit air circulation path 52 formed in the block body 51, and the heat insulating means 58 and the circulation air temperature arranged in the unit air circulation path 52. It consists of the heating means 29 which is an adjustment means, and the air circulation means 42 for forcing air to flow through the unit air circulation path 52. As shown in FIG. In addition, although the lead wire etc. for supplying electric power of a power supply are provided in the heating means 59, illustration of a lead wire etc. is abbreviate | omitted in FIGS. 14A and 14B.

The block 51 is housed in the recess 40b of the unit accommodating portion 40 shown in FIG. 11, and the upper surface of the block body 51 accommodated in the recess 40b is a unit accommodating portion ( It is the same position as the upper surface of 40 or more concave than the upper surface of the unit accommodating part 40. The unit air circulation path 52 is formed inside the block body 51, and both ends of the unit air circulation path 52 are open to the upper surface of the block body 51, respectively.

The air circulation means 42 is comprised by the blowing fan, such as an axial flow fan and a sirocco fan, for example, The said air circulation means 42 is arrange | positioned at the edge part of the unit air circulation path 52 in this 3rd Example. In addition, the air in the upper air flow unit 5 is sucked and discharged into the unit air circulation path 52. By driving the air circulation means 2, the upper air flow means 2 passes through the air circulation means 2 and the unit air circulation path 52 from the upper air flow means 5 as shown by arrow A in FIG. Air circulates in the circulation path back to 5). That is, in this third embodiment, the air circulation passage for circulating air in the mat inner region of the second temperature adjusting portion 3, which is the temperature adjusting region, is formed by the upper air flow means 5 and the unit air circulation passage 52. It is.

In addition, when the body 65 lying on the upper part of the temperature control mat 1 by installing the air circulation means 42 in the opening of the unit air circulation path 52 may feel the air circulation means 42 as foreign matter, For example, a coarse mesh sheet made of a flexible material such as urethane foam or urethane foam composed of a flexible and breathable urethane foam as shown in FIG. 14A is disposed on the air circulation means 2. You may also

The heating means 59 is attached to the inner wall surface of the unit air circulation path 52 through the heat insulating means 58. The heating means 59 is to heat the circulating air passing through the unit air circulation path 52, and any type of heating means can be disposed in the unit air circulation path 52 so as to have a configuration for heating the circulating air. In addition, you may employ | adopt as a heating means 59 suitably. In the third embodiment, however, the heating means 59 is used to adjust the body temperature of the body 65, and thus the temperature variable range of the heating means 59 ends in the low temperature range from room temperature to about 40 ° C. In consideration of this point, it is preferable to set the heating means to be employed as the heating means 59. For example, a heater etc. which integrated the heating element in the silicone rubber as an example of what can be employ | adopted as the heating means 59 are mentioned.

The heat insulation means 58 has the same structure as the heat insulation means 43 of the temperature adjusting unit 41-1, and is for preventing the heat | fever emitted from the heating means 59 from being heat-transferred to the block body 51 for dance. .

The temperature adjusting unit 41-2 shown in Figs. 14A and 14B is configured as described above. In this temperature adjusting unit 41-2, the air circulation means 2 is driven to pass through the inner region of the upper air flow means 5 corresponding to the unit air circulation path 52 and the second temperature adjusting part 3. The circulated air is circulated by the circulation path A to be heated and the circulating air is heated by the heating operation of the heating means 59 (for example, heating at 38 ° C.), whereby the heated circulating air is subjected to the second temperature adjustment unit 3. When passing through the inner region of the upper air flow means (5) corresponding to the body portion (e.g., leg) and circulation air located on the second temperature adjusting section (3) through the upper skin (11) It heat-exchanges and warms the body part located in the 2nd temperature adjustment part 3.

In addition, when the air is circulated as described above, air is blown into the air circulating air path from the outside of the air circulating air path as shown by arrow B in FIG. 14B, but the amount of air blown in is smaller than the amount of circulating air. There is almost no temperature drop of the circulating air due to the blown air.

In the third embodiment, the second temperature adjusting unit 3 is provided with a temperature sensor 15 which is a body temperature detecting means, as shown in Fig. 14B. The temperature adjusting mat 1 of the third embodiment is provided with the same control unit 4 as in the first and second embodiments. The control unit 32 of the control unit 4 receives the body temperature information detected by the temperature sensor 15 at a time, and the heating means such that the received detected body temperature is set in advance to be a target temperature stored in the memory 38. The heating operation of 59 is controlled. As a result, the temperature of the circulating air is controlled to adjust the temperature of the body part located on the second temperature adjusting unit 3. In addition, in the case of controlling the temperature of the circulating air more precisely, for example, a temperature sensor for detecting the temperature of the circulating air is provided in the unit air circulation path 52, and the control unit 32 uses the temperature sensor. The heating operation of the heated water stage 59 may be controlled in consideration of the detected temperature information. In addition, a manual operation means for circulating air temperature adjusting means for manually operating the heating means 29 may be provided. When the manual operation means for circulating air temperature adjusting means is provided, the control unit 32 adjusts the circulating air temperature. When detecting that the manual operation means for the means has been manually operated, the automatic control of the heating means 59 may be stopped to give priority to the manual operation by the manual operation means for the circulation air temperature adjusting means.

This third embodiment is configured as described above. In this third embodiment, there may be a case where the temperature adjusting units 41-1 and 41-2 operate simultaneously and only one of the temperature adjusting units 41-1 and 41-2 operates.

In addition, although the unit accommodating part 40 is comprised by the heat insulating material in this 3rd Example, the constituent material of the unit accommodating part 40 is not limited to a heat insulating material, but can be replaced by a unit, for example, For example, the unit accommodating part 40 may be comprised by the spring unit which arranged many springs conventionally used in a bed, and formed in the basket shape.

In this third embodiment, the heating means 46 of the temperature adjusting unit 41-1 is constituted by a far infrared heater. For example, the heating means 46 may be a near infrared heater. Far infrared rays have a maximum penetration of 2 mm into the skin, whereas near infrared rays have a high penetration of 10 mm into body tissues. For this reason, muscle tissue can be heated by providing a near-infrared heater as the heating means 46. 13A (a) shows an embodiment of a near infrared heater, and FIG. 13B (b) shows a side view of the near infrared heater of FIG. 13B (a). The near-infrared heater shown in FIGS. 13B (a) and 13 (b) includes a printed wiring board 90 made of an epoxy resin, a polyimide film, and the like, a light emitting means 91 mounted on the printed wiring board 90, and an affected part. It is comprised by the positioning means 92 of a positioning position. The light emitting means 91 emits near infrared rays (a wavelength of 1000 nm and its vicinity), and is composed of, for example, a light emitting diode emitting a light having a wavelength of 940 nm. In the example shown in FIG. 13B, a plurality (for example, 16) light emitting means 91 are arranged in a matrix form. The positioning means 92 serves as a reference for the arrangement position of the light emitting means 91 when viewed from the outside of the mat, thereby positioning the body part of the object to be heated (the treatment object) at the arrangement position of the light emitting means 91. For this purpose, for example, the light emitting unit (for example, a red light emitting diode of 700 nm) is constituted. In the example of FIG. 13B, the positioning means 92 is provided at four corner portions of the arrangement area of the light emitting means 91 arranged in a matrix form.

In the case where the heating means 46 made of the near-infrared heater is provided in the temperature adjusting unit 41-1, drive control of the heating means 46 is performed by the control part 32 similarly to the above. In addition, a manual operation means for the heating means 46 may be provided. When the manual operation means for the heating means 46 is provided, the control unit 32 controls the heating means ( Automatic control in 46) is stopped to give priority to manual operation. In addition, in the example of FIG. 13B, the light emitting means 91 is mounted on a printed board which is a flat plate, but has, for example, a curved surface that allows the body to efficiently radiate the light emitted from the light emitting means 91. The light emitting means 91 may be provided on the curved surface of the mounting table.

In addition, in this third embodiment, the heating means 46 is provided as the wound treatment means. For example, other affected skin treatment means such as an ultrasonic output means for outputting vibration energy may be provided instead of the heating means 46. . Even in the case of providing the affected area treatment means such as the ultrasonic output means, the control unit 32 is provided with a configuration for controlling the drive of the affected area treatment unit in accordance with a predetermined control program. In addition, a manual operation means of the affected part treatment means may be provided. In this case, when the manual operation means is operated manually, the control unit 32 is configured to stop the automatic control of the affected part treatment means and give priority to the manual operation.

A fourth embodiment will be described below. In the description of the fourth embodiment, the same reference numerals are given to the same constituent parts as those of the first to third embodiments, and the overlapping description of the common parts is omitted.

In the fourth embodiment, as shown in the schematic cross-sectional view of FIG. 17, the temperature adjusting mat 1 is similarly to the first embodiment in the lower air flow means 6, the channel control means 7 and the upper air flow. The means 5 are sequentially laminated from the bottom, and the laminate has a configuration covered by the skin consisting of the upper skin 11 and the lower skin 12.

In this fourth embodiment, the surface portion of the temperature adjusting mat 1 corresponding to the body portion from the head portion to the knee portion of the body 65 lying on the temperature adjusting mat 1 is set in advance as the temperature adjusting region. have. The flow path control means 7 is provided with a through hole 17 in each of a position corresponding to the end of the head side of the temperature adjusting target region and a position corresponding to the end of the knee side of the temperature adjusting target region. Further, the lower air flow means 6 is formed with a recess 18 over an area between the formation positions of the two through holes 17 of the flow path control means 7. The concave portion 18 is provided with an air circulation means 10 at a position corresponding to an end of the head side of the temperature adjustment target region, and is arranged adjacent to the air circulation means 10 to provide heat exchange means 8. This is arranged. The air circulation means 10 is constituted by a blowing fan such as a sirocco fan, and in this fourth embodiment, the internal air of the upper air flow means 5 is sucked through the through hole of the flow channel control means 7, It is arranged to discharge toward the recessed portion 18 of the lower air flow means (6). The heat exchange means 8 is provided in the concave portion 18 of the lower air flow means 6, that is, on the flow path of the air discharged from the air circulation means 10 to adjust the temperature of the discharged air. For example, it is comprised by the Peltier module, heater, etc. which were described in 1st Example.

In this fourth embodiment, the air in the upper air flow means 5 is sucked into the air circulation means 10 through the through hole of the flow path control means 7 by driving the air circulation means 10, It is discharged toward the recessed part 18 of the air flow means 6. Thus, the discharged air is temperature-controlled by the heat exchange means 8, and the temperature-controlled air is flow path control means 7 at a position corresponding to the recessed portion 18 and the end of the knee side of the temperature adjustment target region. It passes through the through hole 17 of the) to reach the upper air distribution means (5). That is, the through hole of the upper air flow means 5 and the flow channel control means 7 and the recess 8 of the lower air flow means 6 and the flow channel control means 7 are driven by the air circulation means 10. The air circulates through the through holes 17 in order. That is, in this fourth embodiment, the air is introduced into the mat inside area of the temperature adjustment target area by the recessed portion 18 of the upper air flow means 5, the channel control means 7 and the lower air flow means 6. An air circulation passage for circulating is constructed. A part of this air circulation passage is formed along the surface of the mat surface of the region to be adjusted in temperature, and heat exchanges through the mat skin of the circulating air temperature-controlled by the heat exchange means 8 and the body portion on the temperature region to be adjusted. By this, the temperature of the body part on the temperature adjustment target region can be adjusted.

16 is a plan view of the temperature adjusting mat 1 of the fourth embodiment as seen from above. As shown in Figs. 16 and 17, the temperature adjusting mat 1 of the fourth embodiment is provided with a plurality of temperature sensors 56, which are body temperature detecting means, in the temperature adjusting target region on the mat surface. The temperature sensor 56 crosses, for example, a line that crosses a position corresponding to the back portion of the body 65 lying on the temperature adjusting mat 1 and a position corresponding to the waist of the body 65. A dotted line is arrange | positioned along each line of the line of a form, and is fixed to the upper skin 11 by fixing means, such as an adhesive agent. The temperature sensor 56 is a sensor which senses the body temperature of the body 65, and is comprised by having the structure which installed the thermistor, a platinum resistor, or a thermoelectric pair in the front end of a thin line, for example.

In this fourth embodiment, a plurality of body pressure detecting means 57 serving as body state detecting means is disposed in the mat inside area of the temperature adjusting target area. The body pressure detecting means 57 detects the body pressure of the body 65, and is composed of, for example, a strain gage provided at the end of a thin line or a pressure sensor in the form of a plane. As the pressure sensor in the planar shape, for example, a metal thin film is provided on both upper and lower surfaces of a thin dielectric sheet made of plastic (for example, soft polyurethane, etc.), ceramic, or the like. There exists a structure which detects an applied pressure using the change of the capacitance between the said metal thin films (decompression sensor). There is also a configuration in which a plurality of piezo elements (PIEZO) which cause a voltage change by applying pressure with a planar pressure sensor are arranged side by side in a planar shape at intervals.

In this fourth embodiment, the body pressure detecting means 57 is provided in the form of being inserted between the upper air flow means 5 and the flow path control means 7, whereby the upper part of the temperature adjusting mat 1 The body pressure change can be detected with good sensitivity while preventing the body 65 from feeling the body pressure detecting means 57 as a foreign matter.

In this fourth embodiment, a control unit 4 is provided as in the first embodiment, and the control unit 4 includes a control unit 32 and a body temperature data processing unit 34 as shown in the block diagram of FIG. 19. ), A memory 38, a body pressure data processor 55, and a counter 62.

The body temperature data processing unit 34 receives temperature information (temperature information) detected by the plurality of temperature sensors 56 at every hour (for example, every 10 seconds), and compares the temperature information received at the same time point with each other, The highest detected value of this temperature information is output as the body temperature (skin temperature) of the body 65. Further, in reality, since the body 65 often wears clothing, the detection temperature by the temperature sensor 56 is, for example, about 0.3 to 0.5 ° C lower than the actual skin temperature of the body 65. Therefore, for example, a predetermined margin value (for example, 0.5 ° C) may be added to the detected temperature by the temperature sensor 56, and the value after the addition may be the body temperature (skin temperature) of the body 65. .

The body pressure data processing unit 55 receives each detected value of the plurality of body pressure detecting means 57 at each time (for example, every 10 seconds). By the way, for example, if the body 65 lying on the upper part of the temperature adjusting mat 1 changes its posture by turning the body in the direction of the arrow A as the center of gravity moves from the b position in FIG. 16 to the c position, The detected value of the body pressure detection means 57 at the b position (see solid line b in FIG. 18) decreases, and the detected value of the body pressure detection means 57 at the c position (see solid line c in FIG. 18) increases. Thus, the attitude | position of the body 65 on the temperature adjustment mat 1 through the change of the detection value of the body pressure detection means 57 (for example, by the frequency | count of the peak rise of the detection value of the body pressure detection means 57). You can see the state of change. In addition, in the value output from the body pressure detecting means 57, vibration of about 4 to 6 Hz due to heart rate, breathing, etc. of the body 65 appears as a noise component. In the fourth embodiment, filter means such as a low pass filter is used. By this, the noise component is attenuated from the detected value of the body pressure detecting means 57, and the detected value of the body pressure detecting means 57 after the noise attenuation is received by the body pressure data processing unit 55.

The body pressure data processing unit 55 monitors the change in the detected value of each body pressure detecting means 57 that is received, and the threshold value in which the magnitude of the detected value is preset for each of the detected values of the body pressure detecting means 57. The peak rise that is greater than or equal to A is counted using the counter 62.

In this fourth embodiment, the target temperature data, which is a reference for the body 65 on the temperature adjusting mat 1, is stored in advance in the memory 38. In addition, the memory 38 adjusts the temperature based on the state information of the body 65 (information of the peak number of detected values of the body pressure detecting means 57 counted by the counter 62 in the fourth embodiment). Data for setting (changing) the target temperature of the body 65 on the target area is set in advance and stored as target temperature setting data. The control part 32 accepts the counter value of the counter 62 at every time, and sets the frequency of the detection value peak rise of any one body pressure detection means 57, for example between predetermined time (for example, 10 minutes). When detecting that the number of times (for example, two or more times) is reached, the target temperature is set and changed in a direction lower than, for example, the reference target temperature based on the target temperature setting data of the memory 38.

In addition, the control part 32 is the target temperature based on the target temperature data of the said reference | standard or the body temperature (skin temperature) output from the body temperature data processing part 34, or the target temperature after a change when the target temperature is set and changed as mentioned above. It is provided with the structure which performs drive control of the air circulation means 10 and the heat exchange means 8 so that it may become so.

In this fourth embodiment, the temperature of the air circulating in the temperature adjusting mat 1 is adjusted by the control operation of the control unit 32 as described above, and the temperature of the body 65 on the temperature adjusting mat 1 can be adjusted. Can be. Thereby, for example, the control unit 32 controls the operation of the heat exchange means 8 by using the target temperature data A as shown in the first embodiment as the target temperature data as a reference, whereby the temperature adjusting mat 1 When the body 65 is just lying on the upper part, the body temperature of the body 65 is adjusted to be slightly high so that the blood vessels in the skin of the body 65 are opened, and then the body temperature of the body 65 can be slowly lowered. As a result, the body 65 lying on the upper portion of the temperature adjusting mat 1 can be comfortably asleep. In addition, when the body is not sleeping well, the body temperature of the body 65 is high, and the blood vessels under the skin surface are open. When the body cannot be able to sleep like this, the movement of the body such as turning over is increased, so that the controller 32 The body temperature of the body 65 can be lowered by changing and setting in the direction of lowering the target temperature based on the detected value of the body pressure detecting means 57 and controlling the operation of the heat exchange means 8 based on the target temperature after the change. Thus, the body 65 can be quickly asleep.

Also in this fourth embodiment, like the first embodiment, an outside air temperature sensor 36 which is an external detecting means for detecting the ambient temperature of the temperature adjusting mat 1 is provided, and the outside air temperature sensor ( Based on the ambient temperature detected by 36), the data for setting (changing) the target temperature is determined in advance and given as target temperature setting data. And the control part 32 may be provided with the structure which sets and changes the target temperature of the body part on a temperature adjustment target area | region based on the detection value of the outside temperature sensor 36 and the target temperature setting data of the said memory 38. . In addition, a humidity sensor 49, which is a physical state detecting means for detecting the sweating state of the body 65 on the mat, is provided, and the control unit 32 adjusts the temperature as described above using the detected value of the humidity sensor 49. A configuration for setting and changing the target temperature of the body part on the target area may be provided.

The fifth embodiment will be described below. In addition, in description of this 5th Example, the same code | symbol is attached | subjected to the component same as each of 1st-4th Example, and the overlapping description of the common part is abbreviate | omitted.

In the fifth embodiment, in addition to the configuration of each of the first to fourth embodiments, for example, as shown in a schematic cross-sectional view of FIG. 20, the temperature adjusting mat 1 has a blowout opening 60 and an outside air intake opening 61. ) Is installed. The blowout port 61 is a discharge port for releasing a part of air in the mat. The outlet 61 is provided in the vicinity of the path of the circulation air driven by the first and second air circulation means 10 and 16 on the side of the temperature adjusting mat 1, and a part of the circulation air is provided. It blows out from the blower outlet 60 toward the outside.

The outside air inlet 61 is a blower in which external air is blown into the mat in order to compensate for the amount of air discharged. The outside air intake port 61 is a portion of the side of the temperature control mat 1 that faces the blowout port 60 and is located near the circulating air driven by the first and second air circulation means 10 and 16. It is provided in the part, and it enters into the flow of circulation air, and outside air is blown in into a mat through the outside air intake port 61. As shown in FIG. The outside air inlet 61 is provided with a humidity control vent means 54 for lowering the humidity of the outside air entering the mat and a filter for removing dust in the outside air. The ventilation means 54 for controlling humidity has a configuration in which a hygroscopic material such as a desiccant such as silica gel or zeolite is incorporated, and a heater for heating and drying the outside air is provided. By providing the said humidity control ventilation means 54, the humidity of the outside air blown in into a mat can be reduced, and generation | occurrence | production of dew condensation, mold, etc. in a mat which arises from high humidity can be suppressed.

When the temperature adjusting mat 1 of the fifth embodiment is used for a first aid stretcher or the like, by covering the body (patient) 65 on the temperature adjusting mat 1 with a blanket or the like, the outlet 60 is covered with a blanket or the like. Since the air discharged from the blowout outlet 60 enters into the needle bed, the air discharged from the blowout outlet 60 can be brought into contact with the body 65 on the temperature adjusting mat 1. Since the released air is temperature-controlled, the temperature-controlled air can rapidly raise or lower the body temperature by touching the body 65.

A sixth embodiment will be described below. In the description of the sixth embodiment, the same reference numerals are given to the same constituent parts as those of the first to fifth embodiments, and the overlapping description of the common parts is omitted.

FIG. 15A is a schematic cross-sectional view of the temperature adjusting mat 1 of the sixth embodiment, and FIG. 15B is an excerpt of the specific components of the sixth embodiment of the temperature adjusting mat 1 of FIG. 15A. In this sixth embodiment, the first temperature adjusting unit, which is the temperature adjusting target region, is set to a wide area corresponding to, for example, the head of the body 65 lying on the upper part of the temperature adjusting mat 1 to the waist. As the second temperature adjusting section, which is the adjusting target region, is set to a narrow region corresponding to the waist of the body 65, for example, the narrow temperature adjusting target region overlaps a part of the wide temperature adjusting target region. It is.

In the sixth embodiment of the temperature adjusting mat 1, as in the first embodiment, the lower air flow means 6, the channel control means 7 and the upper air flow means 5 are stacked in this order from the bottom. The laminate has a configuration in which the laminated body is covered with a matte skin consisting of an upper skin 11 and a lower skin 12. The through-holes are provided in the flow path control means 7 at positions corresponding to both end portions of the first temperature adjusting portion, and at the same time, the through-holes are provided at positions corresponding to the end portions of the second temperature adjusting portion in the region between the through-holes. The upper surface of the lower air flow means 6 constitutes an air flow passage for passing air from one through hole installed in the flow passage control means 7 to the other through hole corresponding to both ends of the first temperature adjusting portion, respectively. The recessed part 18 is formed. Moreover, the air circulation means 10, 16, 64 which consists of blowing fans, such as a sirocco fan, is arrange | positioned in the formation area | region of the said three through-holes formed in the flow path control means 7, respectively.

In the sixth embodiment, for example, the wide air as shown by the solid arrow b in the temperature adjusting mat 1 is driven by driving the first air circulation means 10 and the second air circulation means 16. 1 It can generate air circulation in the mat internal area of the temperature control part. In order to adjust the temperature of the circulating air, a heat exchange means 8 having the same configuration as that of the heat exchange means 8 shown in the first embodiment is arranged on the discharge side of the first air circulation means 10. Also in this sixth embodiment, the temperature adjusting mat 1 is provided with a control unit 4, and the control unit 32 constituting the control unit 4 is a temperature sensor 56 which is a body temperature detecting means provided on the mat surface. Has a configuration in which drive control of the heat exchange means 8 is performed such that the body temperature of the body 65 detected by the target temperature becomes a predetermined target temperature. As a result, the temperature of the circulating air according to the driving of the air circulation means 10 and 16 is adjusted so that the body portion (for example, the portion extending from the head of the body 65 to the waist) is located on the wide first temperature adjusting portion. ) Temperature can be adjusted. For example, in summer, when the target temperature is set low, the temperature of the circulating air is lowered to lower the body temperature of the body part located on the first temperature adjusting unit.

In addition, by activating the air circulation means 16, 64, air circulates in the path | route as shown by the arrow (a) of the dotted line of FIG. 15 in the mat inner area of a 2nd temperature adjustment part. In order to adjust the temperature of the circulating air, for example, heat exchange means 62 such as a heater is provided. In addition, the control unit 32 of the control unit 4 is configured to perform drive control of the heat exchange means 62 so that the body temperature of the body 65 detected by the temperature sensor 56 of the mat surface portion becomes a preset target temperature. Have As a result, the temperature of the circulating air driven by the air circulation means 16 and 64 is adjusted, and the temperature of the body part (for example, the waist of the body 65) located on the narrow second temperature adjusting part can be adjusted. have. For example, by setting the target temperature high, a local body part (eg, waist) located on the second temperature adjusting part can be warmed, for example, the waist part of the body 65 can be treated by heat. have.

As described above, in the sixth embodiment, the temperature adjustment of the wide area of the body 65 and the local temperature adjustment of the body 65 can be switched. In addition, by simultaneously driving the air circulation means 10, 16, 64, the air circulation as shown by the arrow (a) of the dotted line in FIG. 15 and the air circulation as shown by the arrow (b) of the solid line are inside the temperature adjusting mat. Can generate both.

A seventh embodiment will be described below. In addition, in description of this 7th Example, the same code | symbol is attached | subjected to the same structural part as each of 1st-6th Example, and the overlapping description of the common part is abbreviate | omitted.

In the seventh embodiment, instead of providing the circulating air temperature adjusting means in the mat, for example, as shown in a schematic sectional view of the temperature adjusting mat in Fig. 22, the heat exchange means 8 (9) which is the circulating air temperature adjusting means. The heat exchange unit 78 (79), which is a circulating air temperature adjusting unit incorporating the inside, is externally provided on the outside of the mat, and a part of the air circulation passage is formed in the heat exchange unit 78 (79). Configurations other than this configuration are the same as in the above embodiments.

In the example of FIG. 22, through-holes are formed in the surface of the mat to communicate the air circulation passage in the mat and the air circulation passage formed in the heat exchange unit 78 (79). In addition, the air circulation means 10 and 16 constituted by, for example, a blower fan for circulating air through the air circulation passages formed in the mat and in the heat exchange unit 78 (79) are shown in FIG. In the example, it is arrange | positioned in a heat exchange unit.

In this seventh embodiment, part of the air circulation path is formed in the outer heat exchange unit, so the air circulation region is widened. For this reason, when the preset temperature adjusting target region is narrow, for example, the heat insulating means 74 is provided on the inner surface of the upper skin 11 so as to correspond to a region other than the temperature adjusting target region.

In addition, this invention is not limited to the form of each Example of 1st-7th, Various embodiment can be employ | adopted. For example, in each of the first to seventh embodiments, the upper air communicating means 5 has the configuration shown in FIG. 4, but the upper air communicating means 5 is not limited to the configuration of FIG. 4. An appropriate configuration may be employed as long as it has a cushioning property and allows air distribution (for example, having a degree of air circulation of 100 (cm 3 / cm 2 / s or more) of fragile air permeability according to JIS regulations). . For example, the upper air distribution means 5 may be formed in a basket shape by a material such as plastic or metal. In addition, the upper air flow means 5 may be made of a laminate formed by laminating a thin, soft fabric with a thick structure on top of a highly breathable fabric or a urethane foam containing a slit. In this case, it is possible to prevent the body 65 lying on the upper part of the temperature adjusting mat 1 from giving a foreign object or discomfort due to the structure of the upper air distribution means 5. In addition, the upper air distribution means 5 may have a structure as shown in FIG. In the example of FIG. 21, the upper air flow means 5 is a three-dimensional fabric or the like disposed on the upper side of the low rebound urethane foam 69 and the low rebound urethane foam 69 which are bimodal and low elastic materials. It consists of a highly breathable material 70 made. Inside the low-repulsion urethane foam material 69, a plurality of empty passages 71 for forming an air circulation passage are provided. In addition, a plurality of openings 72 are formed on the upper surface of the low-elasticity urethane foam material 69 to communicate with the air passages 71, and the openings 72 pass through the air passages 71 to allow the inside of the mat to pass through. Heat exchange between the air circulating and the body 65 on the temperature adjusting mat 1 is efficiently realized.

In addition, in the sixth embodiment, as shown in Fig. 15A, the temperature adjustment of the first temperature adjusting part and the temperature adjusting part of the second temperature adjusting part on the mat surface are simultaneously performed using air circulation. When the 2nd temperature control part overlaps with a part of, the 2nd temperature control part which is a narrow side may be made into the structure which performs temperature adjustment using radiant heat, such as far-infrared rays, instead of temperature adjustment using air circulation. Thereby, when the temperature adjustment of each of the first and second temperature adjusting units is performed at the same time, the temperature control of the circulating air for adjusting the temperature of the first temperature adjusting unit can be performed with high accuracy. That is, since the 2nd temperature control part overlaps a part of 1st temperature control part, as shown in FIG. 15A, the part which the circulating air corresponding to a 1st temperature control part, and the circulating air corresponding to a 2nd temperature control part mix. This happens. The mixing of the circulating air makes it difficult to control the temperature of the circulating air. On the other hand, the first temperature control unit is configured to adjust the temperature by using the circulating air, and the second temperature control unit is configured to adjust the temperature by using the radiant heat rather than the circulating air, so that the temperature control of the circulating air becomes easy and the precision is improved. Can increase.

As described above, in the case where the second temperature adjusting section overlaps with a part of the first temperature adjusting section, the temperature adjustment of the wide first temperature adjusting section is performed using air circulation, and the temperature adjustment of the narrow second temperature adjusting section is, for example. , By using radiant heat such as far-infrared rays, for example, to warm a wide body part (for example, a body part extending from the back to the waist) located on the first temperature adjusting part, and having a temperature higher than the warming temperature. This makes it easier to warm up a local body part (eg, waist) located on the second temperature adjustment part.

Further, in place of the temperature adjusting unit 41-1 shown in the second embodiment, as shown in FIG. 23, the temperature adjusting unit 86 for adjusting the temperature of the body part on the temperature adjusting target region using air circulation. ) May be installed. The temperature adjusting unit 86 has a container 77 having an upper surface opening, and heat insulating means disposed in the container body 77 and the concave portion 44a formed in the outer body body 44. (43) and the heating means 46, the cover means 45 which are arrange | positioned in the form which closes the opening part of the recessed part 44a of the outer enclosure 44, and the flow path laminated | stacked and arrange | positioned above the outer enclosure 44 The control means 7, the upper air flow means 5 stacked on the flow path control means 7, and the air circulation means 75 comprising a blower fan and the like are stored. In the example of FIG. 23, the upper air distribution means 5 and the channel control means 7 are respectively the upper air distribution means 5 and the channel control means 7 shown in the first to seventh embodiments, respectively. It has the same configuration. In addition, the enclosure 44, the heat insulation means 43, the heating means 46, and the cover means 45 are the enclosure 44 and the heat insulation means of the temperature adjusting unit 41-1 shown in the second embodiment, respectively. 43, the heating means 46, and the cover means 45 have the same structure, respectively. The through-holes 17 are formed in the flow path control means 7 and the cover means 45 of the temperature adjusting unit 86 in correspondence with the opposite edges of the recess 44a of the outer enclosure 44, respectively. The air circulation means 75 is arrange | positioned in the formation area of the through-hole 17 on one side. The air circulation as shown by arrow M in FIG. 23 is generated by the driving of the air circulation means 75. The heating means 46 which is a heat exchange means is provided on this air circulation environment path.

The temperature adjustment unit 86 shown in FIG. 23 is comprised as mentioned above, and even when such a temperature adjustment unit 86 is provided, the control of the control part 32 of the control unit 4 similar to each said Example is carried out. By the operation, the driving of the heating means 46, which is the circulation air temperature adjusting means, is controlled. As a result, the circulating air driven by the air circulation means 75 is temperature-controlled by the heating means 46, and the temperature-regulated circulating air is with the body part located on the mat surface portion on the temperature adjusting unit 86. The temperature of the body 65 is adjusted by heat exchange through the upper skin 11 in between.

In addition, the temperature adjusting mat 1 may be configured such that a plurality of mat portions 80, 81, and 82 are connected by a connecting portion 84 to form a single mat, for example, as shown in FIG. 24A. . By constituting the temperature adjusting mat 1 in this manner, it is easy to fold the temperature adjusting mat 1. In the example of FIG. 24A, the surface of the mat part 81 is set to the temperature adjustment target area | region, and the mat part 81 has an internal structure as shown to typical sectional drawing of FIG. 24B. That is, the mat 81 is the lower air flow means 6, the first flow path control means 79, the second flow path control means 78 and the upper air flow means 5 are laminated in order from the bottom, This laminated body has the structure covered by the mat skin which consists of the upper skin 11 and the lower skin 12. FIG. The upper air distribution means 5 has the same configuration as the upper air distribution means 5. Surfaces facing each other of the first flow path control means 78 and the second flow path control means 79 are formed of a smooth surface, and the first and second flow path control means 78, 79 are mutually opposite. The bow can move and be displaced. In each of the first and second flow path control means 78, 79, a plurality of through holes 17a, 17b penetrating in the vertical direction are formed at intervals from each other. On the upper surface of the lower air flow means 6, a recess 18 is formed over the portion between the formation regions of the through holes 17a and 17b of the first and second flow channel control means 78 and 79. . In this recessed part 18, the air circulation means 10 which consists of blowing fans, such as a sirocco fan, is arrange | positioned. By the operation of the air circulation means 10, for example, the air inside the upper air flow means 5 passes through the through holes 17a of the first and second flow channel control means 78, 79 and the air. It is sucked into the circulation means 10 and discharged to the recessed portion 18, and the discharged air passes through the recessed portion 18 to pass through holes 17b of the first and second respective channel control means 78, 79. Exit and return to the upper air distribution means (5). That is, air circulation is generated inside the mat part 81 by the driving of the air circulation means 10. Inside the mat part 81, the circulation air temperature adjusting means (not shown) for adjusting the temperature of the circulation air is provided. Also in this case, the temperature control mat 1 is provided with the same control unit 4 as shown in the above embodiments, and the control unit 4 controls the operation of the circulating air temperature adjusting means. The driving control is performed to adjust the temperature of the circulating air by the driving of the air circulation means 10, whereby the temperature of the body part on the upper portion of the mat portion 81 can be adjusted.

Moreover, it is good also as a structure as shown in FIG. In the example of FIG. 25, the heat exchange unit 87 (88) incorporating the heat exchange means 89 which is the temperature adjustment circulation air temperature adjustment means of the body 65 is externally exterior to the mat. Further, heat transfer means 25 is provided for thermally connecting between the heat exchange means 89 in the heat exchange unit 87 (88) and the mat internal region of the temperature adjustment target region 2 (3). For example, when the heat exchange means 8 of the heat exchange unit 87 is comprised by the Peltier module 22, it is connected to the Peltier module 22 by the cooling operation of the Peltier module 22, for example. The heat transfer means 25 is cooled. On the other hand, the heat of the body part located on the temperature adjusting region 2 is transferred inside the mat, and is heat exchanged with the heat transfer means 25 to lower the body temperature of the body portion on the temperature adjusting region 2. . For example, when the heat exchange means 9 of the heat exchange unit 88 is comprised by the heating means 46, such as a heater, a heating means (for example, by the heating operation of the heating means 46), The heat transfer means 25 connected to 46 is heated. The heat of the heat transfer means 25 is transferred to the body part on the temperature adjustment target region 3, thereby raising the body temperature of the body part on the temperature adjustment target region 3.

Incidentally, in each of the first to seventh embodiments, the temperature adjusting mat 1 has been described using an example of a mat used when the body 65 is laid down, but the configuration shown in each of the first to seventh embodiments is a sofa. It can also be applied to the back.

In each of the above embodiments, a body state detecting means is provided with means for detecting a posture change state or sweating state, and the control unit 32 of the control unit 4 is based on the body state detected by the body state detecting means. Although the control operation is shown, of course, the body state detecting means is provided with means for detecting a body state other than the above for detecting the heart rate, blood pressure, etc. of the body 65, and based on the detection information of the detecting means. The control part 32 may perform a control operation.

In each of the above embodiments, the driving control of the circulating air temperature adjusting means is shown so that the detected value of the body temperature detecting means becomes the target temperature, but, for example, when the physical state detecting means is provided, the control unit is provided. The controller 32 of (4) may be configured to control the circulating air temperature adjusting means so that the detected value of the physical state detecting means becomes a preset value.

In addition, the upper skin 11 shown in each of the above embodiments is made of flexible aluminum or copper of about 80 to 90 mesh on the fiber body constituting the upper skin 11 in order to improve heat exchange of the body 65 more efficiently. You may use a metal mesh made of a high thermal conductor such as calcined carbon.

According to the present invention, at least one partial temperature adjustment region is set on the mat surface, and an air circulation passage for circulating air in the mat inner region of the temperature adjustment region, and forcibly introducing air to the air circulation passage. The air circulation means for circulating and the circulation air temperature adjusting means for adjusting the temperature of the circulating air are provided, and the temperature adjustment of the body part on the said temperature regulation target area | region is carried out by heat exchange with the temperature-regulated circulating air. It was set as the structure to perform. In this configuration, the temperature adjusting region is a partial region of the mat surface, so that temperature adjustment of a part of the body on the mat is possible.

Claims (10)

A temperature adjusting mat having a function of adjusting the temperature of the body on the mat, At least one partial temperature adjustment target area is predetermined on the surface of the body side of the mat, and an air circulation passage for circulating air in the mat internal area of the temperature adjustment target area is part of the mat. It is formed to follow the skin surface of the mat, at least a part of the air circulation passage is made of a highly breathable and highly breathable material, Air circulation means for forcibly circulating air in the air circulation passage, Circulating air temperature adjusting means for adjusting the temperature of the air circulating in the air circulation passage to adjust the temperature of the body part on the temperature adjusting target region; Body temperature detecting means for detecting body temperature of the body part on the temperature adjusting target region; On the basis of the detected value of the body temperature detecting means, a control unit for controlling the driving of the air circulation means and the circulating air temperature adjusting means is provided so that the body temperature of the body part on the temperature adjusting target region becomes a preset target temperature. Temperature control mat. The method of claim 1, Physical state detecting means for detecting a physical state on the mat is provided, and data for setting a target temperature of the body part on the temperature adjusting target area is given in advance based on the physical state detected by the physical state detecting means, The control unit sets the target temperature of the body part on the temperature adjustment target region based on the information of the physical condition detected by the physical condition detecting means and the data, and circulates the air so that the detected value of the temperature detecting means becomes the target temperature. And a driving control of the means and the circulating air temperature adjusting means. The method according to claim 1 or 2, External detecting means for detecting the environmental information outside the mat is provided, and data for setting the target temperature of the body part on the temperature adjusting target area is given in advance based on at least the environmental information detected by the external detecting means. And The control unit sets the target temperature of the body part on the temperature adjustment target region based on the ambient environment information detected by the external detection means and the data, and the air circulation means so that the detected value of the body temperature detection means becomes the target temperature. A temperature adjusting mat, characterized in that for driving control of the circulating air temperature adjusting means. The method according to claim 1 or 2 or 3, On the surface of the body side of the mat, a plurality of temperature adjusting target areas are defined in advance, and air circulation passages, air circulation means, and circulating air temperature adjusting means are provided for each temperature adjusting target area, respectively. And the control unit controls driving of the air circulation means and the circulating air temperature bath constant stage for each temperature adjustment target region. The method according to any one of claims 1 to 4, A temperature regulating mat characterized in that an outlet for discharging a portion of air in a mat is provided, and an air inlet for injecting outside air into the mat is provided to compensate for the amount of air discharged from the outlet. The method according to any one of claims 1 to 5, A circulating air temperature adjusting unit having a built-in circulating air temperature adjusting means is provided outside the mat, and a part of the air circulation passage is formed in the circulating air temperature adjusting unit. The method according to any one of claims 1 to 6, And a body temperature detecting means is provided as a member that can be mounted on the body part on the mat. The method according to any one of claims 1 to 7, A temperature regulating mat, comprising: a wound treatment means for applying energy of heat, light, or vibration to a body part on a mat surface portion of a non-air circulation region other than a region to be temperature controlled by air circulation. The method of claim 8, The control unit performs drive control of the air circulation means and the circulating air temperature adjusting means of the temperature adjustment target region by air circulation, and separately gives the drive control of the affected area treatment means of the non-air circulation region separately from the drive control. Independently based on the control program, simultaneous operation of the treatment by the temperature adjustment of the body part on the temperature adjustment target area by air circulation and the treatment of the affected part of the body part on the non-air circulation area by air circulation A temperature adjusting mat, characterized in that only the operation of adjusting the temperature of the body part on the temperature adjusting target region and the operation of treating only the treatment by the affected area treatment means of the body part on the non-air circulation area are performed. A manual operation means for air circulation means for manually operating the air circulation means of any one of claims 1 to 9, A manual operation means for the circulating air temperature adjusting means for manually operating the circulating air temperature adjusting means of any one of claims 1 to 9; At least one of the manual operation means for affected area treatment means for manually operating the affected area treatment means of claim 9, The control unit controls the automatic control of the air circulation means or the circulating air temperature adjusting means or the wound treatment means when the manual operation means for the air circulation means or the manual operation means for the circulation air temperature adjusting means or the manual treatment means for the wound treatment means is operated manually. And stopping, prioritizing the manual operation by the manual operation means for the air circulation means, the manual operation means for the circulation air temperature adjusting means, or the manual operation means for the wound treatment means.

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