DE19831023A1 - Electrical supply for resistance heating unit for heated cover and heatable rescue system - Google Patents

Abstract

The supply arrangement has at least two accumulators (2,3) that can be connected to a flexible carbon fiber resistive heating layer (1). The electric supply to the resistive heating layer is provided exclusively by at least one of the accumulators that is absolutely separate from the mains or a current generator and earth, whilst the other accumulator(s) is or can be connected to a charger. The connection between the accumulators and the heating layer is interrupted by an on/off switch (9), whilst the accumulators are changed over between supply and charging modes. An Independent claim is also included for a heatable rescue system

Description

The invention relates to an electrical supply device, for one resistance heating layer formed by a flat carbon fiber fabric an electric blanket, with at least one accumulator and a heatable rescue system stem.

From DE 196 42 037 A1 a heating blanket is known in which the flat elec Trisch operable resistance heating layer from a flexible, essentially only Carbon fiber existing layer is formed. As an electrical supply device for the resistance heating layer, for example, a vehicle battery with a ver supply voltage of about 12 volts. The known electric blanket can preferably in medical field. It serves to maintain the Body temperature of patients, for example during an operation or also from Accident victims at the scene of the accident. In particular during an operation, due to the Anesthesia significantly lower the body temperature. For longer operations they are Evidently hypothermic patient. This hypothermia can often be the reason infections. In addition, the recovery period after the Opera is extended tion considerably. The known electric blanket is transverse to its longitudinal extension in several Electric blanket elements divided, with the transverse electric blanket elements since Lich connected to each other by a longitudinal bar through which the current supply lines can be led. This ensures on the one hand that the appropriate body during the operation or during the procedure on the body can be exposed by folding away an electric blanket element so that the attending physician has unhindered access to this part of the body. On the other hand hypothermia of the patient by those still covering the patient's body Electric blanket elements prevented.

The object of the invention is an electrical supply device for the cons auxiliary heating layer of a preferably used in the medical field Electric blanket, in the case of faults and injuries to the resistance heating layer The patient and the attending doctor remain safe, as well as an easy to handle to create a heatable rescue system.

This object is achieved by the characterizing features of Pa Tent claim 1 and claim 8 solved.

In the electrical supply device according to the invention for the cons auxiliary heating layer of an electric blanket, at least two batteries are provided, the are connectable to the resistance heating layer. The electrical supply of the Wi derstandsheizschicht happens exclusively by at least one of the accumulators ren. The or the accumulators, which for power supply to the resistance heater layer is or are connected, are from the grid or another electricity generation ger, z. B. generator, and absolutely separated from ground. It is an electrical cal supply of the resistance heating layer, at which potential freedom is guaranteed is. This is also in the event of malfunctions and / or injuries to the electrical lines and the resistance heating layer endangers the patient or the treating person Doctor avoided. The entire electrical supply is completely separate from Verbin to the supply network, another power generator and ground.

During the power supply of the resistance heating layer by the at least one Accumulator can the other or the other accumulator (s) to a charging device can be connected or connected. When switching the battery lators between charging and supply operation, the electrical connection between interrupted the accumulators and the resistance heating layer. this happens by an on-off switch, which provides an absolute separation between the contr parking heating layer and the batteries during the switching process. Changeover switches that can be operated electromagnetically (relays) are used for switching. By disconnecting the supply circuit during the switching process Sparking on the switch contacts and bouncing of the switch contacts prevent  different. The supply circuit remains off for a few seconds, for example switches so that sparking and bouncing are reliably prevented.

In this way, the batteries can alternate with the resistance layer and the charger.

For temperature control, a target temperature can be specified, the Er range of the target temperature through temperature distribution distributed in the resistance heating layer ler is determined. The temperature control can be done with the help of a central computer nereinrichtung (microprocessor) are performed. This can with respect to the target temperature and other parameters such as B. the respective switching temperature program be mable. The parameters can be set on a display or monitor to be shown. During operation, the temperature measured temperatures are displayed. The device can be protected by fuses be protected in the event of short circuits.

When the electrical supply device is switched on, the electroni cal control device for temperature control subjected to a self-test. Here the parameters are displayed and it can be checked whether these parameters, especially the target temperature is properly set. The heating process can start regardless of whether or not the resistance heating layer connected accumulator or accumulators connected to the charging device are or not. When the target temperature is reached, e.g. B. 37.5 ° C, is by control maintain this temperature. The accuracy in temperature detection is approximately at ± 0.3 ° C.

The central control device (e.g. Microprocessor) signals of the respective temperature sensors, which are in the contr auxiliary heating layer are installed, signals which occur when scanning the battery voltage and a signal that indicates whether the supply voltage (approx. 12 volts) is present.  

The accumulator or accumulators, which are are not connected to the resistance heating layer during the supply operation bes of the other accumulator or the other accumulators charged, if this is required. If the capacity of the accumulator in the utility company tors is exhausted, the central control device (microprocessor) turns around switch causes so that the exhausted accumulator or the exhausted accumulator gates can be connected to the charger. The other or the others charged batteries are then used to power the resistance heater layer connected to this, with the newly connected accumulator or the newly connected batteries from the network or a power generator as well are absolutely separated from the mass. The exhausted accumulator or the exhausted Accumulators are being charged. The switchover is preferably dependent of the remaining capacity, preferably about 25% of the remaining capacity of the respective Ver care battery.

Lead accumulators with a high energy density are preferably used. Two identical accumulators are preferably used. With a whole thing 300 watts for the heating phase and about 100 watts for the maintenance The capacity of these batteries will be between 8 and 24 ampere hours preferred at 12 volts. Such batteries are commercially available and how approx. 3 to 10 kg. As a result, a supply operation of each accumulator be maintained for about 30 minutes. With fully charged accumulators, this means oh ne external supply a heating blanket supply of at least one hour guaranteed. A charger is preferably used as the charging device whose function is optimized for quick charging. The charger can also by another 12 volt supply device, e.g. B. on the cigarette lighter plug of a vehicle. Due to the potential freedom of the supply facility The heating blanket can be used in the supply area during an operation on the surgery be grounded ontically. Due to the temperature control an optimal functi on adaptation, e.g. B. temperature setting reached. By the Ver network outages or patient transport times from the operating room  to be bridged over to a sick room. The controlled electrical supply device device can be designed so that it fulfills the MedGV and the EMV.

The wiring and the supply of the resistance heating layer of the electric blanket, which can be designed in such a way as that known from DE 196 42 037 A1 Electric blanket, preferably done with highly flexible silicone-insulated cables. The The resistance heating layer is preferably contacted with the supply conductors ter way with the help of electrically conductive flexible tapes, in particular made of metal, e.g. B. copper with elastic threads and high tensile force in the textile-like counter parking heating layer are sewn. The respective band is also, in particular on both sides provided with a temperature-resistant and non-water-soluble contact paste. To this In this way, a very low contact resistance between copper strips is achieved and the carbon fiber fabric of the resistance heating layer. The width of the copper tape is approx. 8 mm.

The contacting of the resistance heating layer can also be done with the help of a contacting paste, especially silver paste, which are made along two opposite each other lying edge strip of the resistance heating layer, for example by soaking, Im impregnate or the like, is introduced into the carbon fiber fabric.

In particular, the electrical supply device can also be used for a heatable one Rescue system can be used, which in such an inventive way is formed that a blanket is arranged over a thermally insulated lying surface can be, which on its inner side assigned to the lying surface at least one Has resistance heating layer. It can, for example, in the longitudinal direction of the ceiling seen, three resistance heating layers can be provided on the inside of the ceiling.

The lying surface and the ceiling can be connected to each other so that the ceiling can be folded over the lying surface. For example, in Form of loops, stiffening support rods and the like, a support device be provided. Due to the ceiling with the resistance heating layer, can a patient lying on the lying surface during transport or during treatment is kept at normal body temperature.

The invention is explained in more detail with reference to the figures. It shows

Fig. 1 is a block diagram of an embodiment;

2 shows an embodiment for contacting the resistance heating layer.

Fig. 3 is a bottom surface of a blanket, which can occur during a rescue system for use;

Fig. 4 shows another embodiment for contacting the resistance heating layer;

Fig. 5 shows an embodiment of a heatable rescue system, in the form of a foldable rescue blanket.

Fig. 1 shows a block diagram of an embodiment of the electrical supply device. This has two accumulators 2 and 3 , which can alternately be connected to a resistance heating layer 1 of an electric blanket. The Wi derstandsheizschicht can be divided into several heating layer elements, as is known from DE 196 42 037 A1. The resistance heating layers 1 of the various heating elements are connected in parallel to the supply voltage, approximately 12 volts, of a respective accumulator 2 , 3 . In the illustrated embodiment, the accumulator 2 is in the supply mode, while the accumulator 3 in the charging operation is connected to a charging device 4 . The switchover between supply operation and charging operation takes place by means of electromagnetically controlled switches 6 , 7 , whereby a relay coil 8 can be seen for both or for the respective switch.

In Fig. 1 is an embodiment with two identical batteries, especially lead-acid batteries of high energy density, is shown. If necessary, more batteries can be connected to one or more electric blankets at the same time to supply the electric blanket, with the remaining batteries in the charging unit being connected to the charging device 4 .

Each resistance heating layer 1 of a heating element is assigned a temperature sensor 10 . The respective temperature sensors 10 are connected to an electronic control device (CPU, microprocessor). The temperature sensors 10 deliver temperature signals proportional to the temperature of the resistance heating layer 1 to the central control device 5 . In the central control device 5 , a target temperature is also entered, to which the resistance heating layer 1 is to be heated. This target temperature is, for example, 37.5 ° C. For monitoring the supply operation of each connected to the resistive heating layer 1 accumulator (in the figure of the accumulator 2) taps 12, 13 in the supply circuit for the opponent standsheizschicht 1 or Widerstandsheizschichten 1 is provided, in which example as tapped off the respective supplied from the battery supply voltage who that can. This also gives an indication of the remaining capacity of the accumulator currently in the supply mode. The corresponding signal is also supplied to the central control device 5 . In the supply circuit of a respective resistance heating layer 1 there is also power electronics 11 which is controlled by the central control device 5 . Through the power electronics 11 there is a setting of the supply current that is supplied by the connected accumulator to the resistance heating layer 1 . The power electronics 11 are controlled by the central control device 5 as a function of the temperature measured by the temperature sensor 10 . For this purpose, the power electronics 11 can have an electronic power switch, which is switched on and off as a function of the measured temperature of the resistance heating layer 1 .

If it is determined by the central control device 5 , for example on the basis of the interferences from the supply voltage signal determined from 12 and 13 , that the remaining capacity of the connected accumulator (accumulator 2 in FIG. 1) has dropped so far that the other accumulator (accumulator 3 in Fig. 1) must be switched, the central control device 5 supplies the relay coil 8 with a corresponding switching signal. Before initiating the switching process, however, by opening an on-off switch 9 , the supply device consisting of the accumulators 2 , 3 is separated from the resistance heating layers 1 . As soon as the switching process is carried out, ie as soon as the accumulator 3 is connected to the resistance heating layer 1 or the resistance heating layers 1 and the accumulator 2 is connected to the charging device 4 and no sparking and no bouncing of the contacts of the switches 6 and 7 can no longer take place , The on-off switch 9 is closed again, so that the electrical connection between the battery 3 and the resistance heating layer 1 or the resistance heating layers 1 is established.

The controlled heating process of the connected resistance heating layers 1 then takes place. With the central control device 5 , a display device 14 can be connected, with which the individual parameters which are required for controlled heating operation can be displayed for monitoring the operation of the electrical supply device.

The contacting of the resistance layer 1 is shown in a sectional representation in FIG. 2. For this purpose, a flexible electrically conductive tape, in particular made of copper, is connected to an electrical line 18 of the wiring, for example by soldering. This band 17 is sewn with the existing resistance heating layer 1, which consists in particular of a carbon fiber fabric. For this elastic sewing threads 16 are used ver. The tape is provided on both sides with a temperature-resistant and non-water-soluble contact paste 15 . The resistance heating layer 1 is on both sides of the coated tape, so that the coated tape is sewn into the carbon fiber fabric of the resistance heating layer 1 . For this purpose, the resistance heating layer can be folded around the band 17 coated with the contact paste 15 . The sewing of the two resistance heating layers takes place with high tensile force, so that a high contact pressure between the coated band 17 and the double-sided sewn resistance heating layer 1 is created. This results in a low contact resistance at the contact point, so that low losses occur and desired heating occurs on the surface of the resistance heating layer.

In FIG. 4, a further embodiment is for contacting the abutment standsheizschicht 1 is shown. Here, a contacting strip 19 is formed on two opposite edges of the resistance heating layer 1 ( FIG. 3), in the carbon fiber fabric of which a contacting paste, in particular silver paste, is introduced, for example, by soaking the carbon fibers of the fabric. The two contact strips 19 are electrically connected to the electrical conductors 18 in a known manner. The electrical conductors 18 are guided in a lateral cable guide 26 along the Widerstandsheizschichten 1, in FIG. Exemplary embodiment of a rescue sheet 3 are shown in which three-area resistance heating layer 1 next to each other on the underside of the ceiling. This blanket can be a foldable blanket 28 ( FIG. 5), an emergency blanket 20 .

The emergency blanket 20 has a lying surface 22 which consists of a soft material and is thermally insulating. The lying surface 22 is applied as an insulation layer to an outer envelope 21 of the emergency blanket. The outer shell 21 consists of a waterproof, washable, tearproof, windproof and blood-resistant material. The outer shell 21 is designed as a continuous web and has a width such that the ceiling 28 , which has the resistance heating layers 1 ( FIG. 3) on its inside, is also included. Along a in the longitudinal direction of the outer shell 21 or the rescue blanket 20 folding area which is between the resistance heating layers 1 and the lying surface 22 and extends approximately parallel to the cable guide 26 in the longitudinal direction of the rescue blanket 20 , the blanket 28 in the direction of an arrow 27 can be folded down and arranged above the lying surface 22 . A patient who rests on the lying surface 22 is then covered by the heated blanket 28 . The outer shell 21 of the blanket 28 and the outer shell 21 of the lying surface 22 can also be connected to one another by another material which can be folded in the longitudinal direction of the rescue blanket 20 .

The resistance heating layers 1 can have envelopes 25 which are skin-friendly, temperature-neutral, opaque, blood-resistant, autoclavable and sterilizable and washable at a higher temperature (eg 95 ° C.). The respective resistance heating layers 1 have the temperature sensors 10 , which are connected to the electrical supply device in the manner shown in FIG. 1.

The total width of the emergency blanket 20 can be approximately 140 cm. The length of a respective segment of the resistance layers 1 ( FIG. 3) is approximately 67 cm and the width is 44 cm.

As can be seen from FIG. 5, on the outside of the outer shell 21 , in a region to the side of the lying surface 22, carrying loops can be provided as a carrying device 24 , which loops are connected with a fastening strand 29 , if necessary. Other suitable suspension means can also be used.

Velcro strips 23 can be provided on the inside of the outer cover 21 . The covered resistance heating layers 1 can be fastened to the inside of the outer shell 21 by means of the Velcro strips 23 . The lying surface 22 can also have Velcro strips. The cover 28 can have, at its outer edge, closure means (not shown in more detail) which, with closure means in the region of the outer edge of the lying surface 22, serve to fix the cover 28 folded over the lying surface 22 .

The power supply of the resistance heating layer or resistance heating layers 1 in the embodiment of FIGS. 3 and 5 can with one or more batteries, optionally with a control device, as shown in FIG. 1, or by an existing generator in a rescue vehicle, for . B. Lichtma machine or the vehicle battery.

Reference list

1

Resistance heating layer

2nd

accumulator

3rd

accumulator

4th

Charger

5

Central control facility

6

switch

7

switch

8th

Relay coil

9

On-off switch

10th

Temperature sensor

11

Power electronics

12th

Tap

13

Tap

14

Display device

15

Contact paste

16

Sewing threads

17th

electrically conductive tape

18th

electrical line

19th

Contact strips

20th

Rescue blanket

21

Outer shell

22

Lying surface

23

Velcro straps

24th

Carrying device

25th

Cover

26

Cable routing

27

Folding direction

28

blanket

29

Strengthening strand

Claims (10)

1. Electrical supply device for an essentially formed by a flat flexible carbon fiber resistance heating layer of a heating blanket, with at least one battery, characterized in that at least two batteries ( 2 , 3 ) can be connected to the resistance heating layer ( 1 ), the electrical supply of the resistance heating layer ( 1 ) is carried out exclusively by at least one of the accumulators ( 2 , 3 ), which is absolutely separated from the network or a power generator and ground, while the other or the other accumulators can be or are connected to a charging device ( 4 ) , And that an on-off device ( 9 ) is provided, which gates when switching the accumulators ( 2 , 3 ) between charging and supply operation, the electrical connec tion between the batteries ( 2 , 3 ) and the resistance heating layer ( 1 ) interrupts. 2. Electrical supply device according to claim 1, characterized in that to the poles of the batteries ( 2 , 3 ) switches ( 6 , 7 ) are connected, which the batteries ( 2 , 3 ) alternately with the resistance heating layer ( 1 ) and the charging device ( 4 ) connect. 3. Electrical supply device according to claim 1 or 2, characterized records that the switching depending on the remaining capacity, preferably at 25% of the remaining capacity. 4. Electrical supply device according to one of claims 1 to 3, characterized characterized that the electric blanket is grounded.   5. Electrical supply device according to one of claims 1 to 4, characterized in that for contacting in the resistance heating layer ( 1 ) an electrically conductive flexible band ( 17 ) which is coated on both sides with contact paste be sewn. 6. Electrical supply device according to claim 5, characterized in that an edge region of the resistance heating layer ( 1 ) is placed on both sides around the electrically conductive band ( 17 ). 7. Electrical supply device according to one of claims 1 to 4, characterized in that for contacting the resistance heating layer ( 1 ) in the carbon fiber fabric of the resistance heating layer ( 1 ) an electrical contact paste, in particular silver paste, is introduced along a contact strip ( 19 ). 8. Heated rescue system with at least one, in particular heated by an elec trical supply device according to one of claims 1 to 7 and formed by a flat, flexible carbon fiber fabric against standing heating layer, characterized by a thermally insulated lying surface ( 22 ) and a blanket arranged above the lying surface ( 28 ), which has at least one resistance heating layer ( 1 ) on its inner side facing the lying surface ( 22 ). 9. Heated rescue system according to claim 8, characterized in that the blanket ( 28 ) on the lying surface ( 22 ) can be folded. 10. Heated rescue system according to claim 8 or 9, characterized in that a support device ( 24 ) is provided on the lying surface ( 22 ).