NO153246B - MONITORING CLUTCH FOR SIGNAL SENSOR CONNECTION BY A VEHICLE BRAKE DEVICE. - Google Patents

Abstract

1. Monitoring circuit for a signal output circuit on a brake installation of a vehicle, in particular a rail vehicle, the signal output circuit having a switching elemnt (K1, Q5) which is connected to an input signal circuit and which controls an output signal circuit, characterized by - a second switching element (K2, Q6) which is also connected to the input signal circuit and, in series to the first switching element (K1, Q5), also controls the output signal circuit, - a first and a second comparator (G1, G2) and, in series with each of these, a delay element (T1, T2), the first input (a) of the two comparatos (G1, G2) being connected to the input signal circuit, the second input (b) of the first comparator (G1) being connected to a circuit (S3, R7) of the first switching element (K1, Q5) and the second input (b) of the second comparator (G2) being connected to a circuit (S4, R8) of the second switching element (K2, Q6), and the two delay elements (T1, T2) having different delay times, and - a first and a second switch (Q1, Q2), the first switch (Q1) being located in the switching-on circuit of the first switching element (K1, Q5) and being connected to the output of the second delay element (T2), and the second switch (Q2) being located in the switching-on circuit of the second switching element (K2, Q6) and being connected to the output of the first delay element (T1).

Description

Device for use in hospitals for determining a patient's body temperature.

The invention relates to a device for measuring a patient's body temperature and comprises a probe which is intended to be exposed to body heat and then placed in a separate measuring device which indicates the measured temperature.

An unfortunate aspect of the commonly used glass mercury-solve fever thermometers is that they cannot be heat sterilised, and the use of sterilizing liquids is not entirely reliable, in addition to the fact that this often entails disadvantages and always a loss of time. Doctors and nurses in hospitals must be equipped with a large supply of thermometers when they have to serve a number of patients, and the thermometers must be sterilized after each use.

The usual glass thermometers are also quite expensive and can easily break, so that they constitute a significant expenditure item for hospitals and clinics.

The invention provides an inexpensive form of temperature measuring device which makes sterilization unnecessary, while ensuring a completely sterile device for measuring a patient's temperature.

The device according to the invention comprises a device for use at a hospital for determining a patient's body temperature consisting of a probe and a temperature measuring device that indicates the measured temperature, the new and characteristic feature being that the probe is made of a uniform rod-shaped element (11) of plastic material comprising a stem-like handle portion (13) and a tube-shaped end portion (12) co-extending therewith which is designed to be brought into intimate heat-transferring connection with a separate temperature measuring device (10) after first being placed in a heat-absorbing position in a patient's body cavity in the same manner as an ordinary thermometer, and so that the tube-shaped end part will reach the body temperature in a relatively short time and maintain this during the subsequent measurement using said measuring device (10).

As the heat-absorbing probe only serves the purpose of receiving and storing heat from the body or the object whose temperature is to be measured, it can be manufactured so cheaply that it can be thrown away after use. It can be constructed of different materials with the intention that it should retain such a quantity of heat at the temperature level of the body being measured that in the few seconds necessary to transfer it from the place of heat collection to the meter, no heat loss occurs. Usually, the probe will have sufficient size and be composed of such materials that a relatively large amount of heat is required to raise the temperature one degree, i.e. that it has a high specific heat. The probe should preferably also comprise a heat-conducting body of relatively large area, which should come into direct contact with the thermal resistance device in order to transfer the heat to it as quickly as possible.

The thermal resistance device has a low specific heat, so that the transfer of a relatively small amount of heat contained in the collection device is sufficient to raise the temperature of the thermal resistance device to that of the collection device.

The invention shall be described in more detail with the help of the drawings, where Fig. 1 shows in perspective the measuring device and the opening through which the probe is inserted, as such a probe is also shown in position immediately for insertion into the measuring device.

Fig. 2 shows the probe and the measuring device in central section.

Fig. 3 shows a connection diagram for the measuring device.

The measuring device in fig. 1 essentially consists of two parts, namely the micro- or milliammeter 10' and the probe 11. This probe consists of a. tube-shaped part 12 and a handle part 13 designed in one with this. Both of these parts are made of a suitable resin material, such as e.g. polypropylene, polyethylene or other suitable plastic. Closely enclosed by the tube-shaped part 12 is arranged a metal sleeve or boss lh whose main part 15 ends at both ends in extended circular flanges 16 which abut against the inside of the rudder 12, whereby an annular air space 17 is provided between the main part 15 and the inside of the rudder 12. The outer flange 16 for the sleeve lh is preferably placed at a small distance from the outer or free end of the rudder 12 in order to provide an insulating air space.

The measuring device 10 is provided with an opening 18, which leads into a chamber 19 which can be dismantled for reasons which will be explained below. Inside the chamber 19 there is mounted a cross piece 20, a thermal resistance device 21 from which leads 22, 23 connected in a circuit which will be described below. The thermal resistance device is provided with a head 23' of a shape and size corresponding to the internal dimensions of the main part 15 of the sleeve 1k. When inserting the probe 11 into the chamber 19, the head 23' will fit closely into the metallic main part 15 for the heat collector and thereby establish a path with relatively high electrical conductivity to the wire or coil of the resistance device which is inside the head 23'.

Fig. 3 shows the electrical amplifier circuit to which the leads 22 and 23 for the thermal resistance device are connected. The circuit comprises an amplifier, preferably in the form of a transistor 2h, the plate 25 of which is connected to ground across a resistor R-^, while the emitter 26 is similarly grounded across a resistor R,-, which, like the resistor R-^ , is of a magnitude of about 180 ohms. One or both of these resistors may be variable to facilitate the calibration of the circuit and to make adjustments to the relative sizes of the resistors.

The collector 27 of the transistor is connected by the wire 28 to a 50 ua microammeter 10'. The coupling receives current from a single electric cell 31, one terminal of which is grounded, while the other via a spring-loaded switch 30 is connected to the ammeter 10' and the sleeve lk.

The transistor 2Li can be of the P-N-P or N-P-N type and is preferably a transistor of the type used for audio amplification.

The effect of the device described above is as follows: The probe or heat collector 11 is placed orally or rectally and allowed to remain there until it has reached the body's temperature. This will usually happen after about a minute. It is then removed and inserted into the chamber 19 of the measuring apparatus 10, where the metal sleeve 1k comes into heat-conducting contact with the rod-like thermal resistance device 21. The switch 30 is preferably pressed down for a few seconds before the probe is fed to the thermal resistance device to bring it to a base -temperature of 33?9°C to 35°C, the thermal resistance device being of a type which at a voltage of 1.h volts is not heated above about 35°C. When the temperature of the thermal resistance device rises to that of the probe, the resistance of the resistance device falls and the current rises. This current rise is amplified, and the amplified current affects the pointer of the ammeter which moves over a suitably calibrated temperature scale. The probe 11 is then removed and discarded.

The heat of the body being measured is absorbed not only by the rudder 12, the mass of air in the annular space 17, the sleeve 1^ and the air in the cylindrical space inside the sleeve, but also by the air in the more or less cylindrical space 1^' between the inner flange 16 and the closed end 12' of the rudder. The air space between the outer end of the sleeve and the open end of the rudder serves to insulate the sleeve. The heat capacity of the probe is so much greater than that of the head of the thermal resistance device that the latter reaches the temperature of the probe without any significant temperature drop in the collector. The device can therefore easily be constructed so that it is accurate to within about 0.2°C, and by using two thermal resistance devices the accuracy can be brought up to about 0.002°C.

It will be obvious that saliva or faecal deposits that occur on the probe will not affect the temperature measurement. On the contrary, the mass that has the temperature to be measured will thereby be increased. This will only contribute to more accurate measurement. As will be easily understood, the greater the mass of the probe, the longer will be the time required for the reading to take place on the meter.

The tubular portion of the probe shall be of a steel barrel suitable for placing under the tongue in the case of oral temperature measurement, having a length of about 12.7 mm to 25j<*>+ mm and an outer diameter of about 8.5 ™ satisfactory. The plastic tube can be about 0.76 mm thick, and it will be understood that the length of the metallic sleeve is considerably greater than the length of the thermal resistance device head with which it cooperates. The length of the thermal resistance device's spindle must be such that the head 23' penetrates up to about the middle of the sleeve.

The chamber 19 with the thermal resistance device is preferably made replaceable for periodic cleaning, and the thermal resistance device can be dismountable from the cross piece 20 to facilitate this cleaning.

As the probe is preferably produced as a disposable unit that can be thrown away after a single use, it can also be produced very cheaply on a large scale and can be packed in sterile form in sealed plastic containers etc. However, it will also be clear that the probe can also be used again after being sterilized, since it can be assembled from parts which, unlike mercury solar thermometers, are not damaged by sterilization temperatures.

It is usually desirable to make the inner surface of the metallic or otherwise thermally conductive sleeve somewhat uneven and also the outer surface of the thermal resistance device head. This can be done by sandblasting and helps to eliminate or break off any adhering insulating film, and promotes better heat conduction from the sleeve to said head.

The cross piece 20 is preferably made from a disc of more or less rigid material. In front of the disc, a relatively smooth and yielding disc 20' of rubber or the like can be placed. to absorb any shock when inserting the probe 11.

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Claims (9)

1. Device for use at a hospital for determining a patient's body temperature consisting of a probe and a temperature measuring device that indicates the measured temperature, characterized in that the probe is produced by a uniform rod-shaped element (11) of plastic material comprising a stem-like handle part (13) and a coaxially with this extending tube-shaped end part (12) which is designed to be able to be brought into intimate heat-transferring connection with a separate temperature measuring device (10) after first being placed in a heat-absorbing position in a patient's body cavity in the same way as a normal thermometer, and so that the tube-shaped end part will reach the body temperature in a relatively short time and maintain this during the subsequent measurement by means of said measuring device (10). 2. Device as stated in claim 1, characterized in that the probe is stopped by polyethylene. 3. Device as stated in claims 1-2, characterized in that the interior of the tube-shaped end part (12) of the probe is dimensioned to be able to receive a thermistor (21) which forms part of an electrical circuit (22 - 28) in the separate temperature measuring device (10). h. Device as specified in any of claims 1-3? characterized in that the tube-shaped end part (12) of the probe has high heat capacity. 5. Device as specified in claim k, characterized in that a largely cylindrical element (1<*>+) is placed in the tube-shaped end part of the probe at a certain radial distance from the tube wall, so that an annular air-filled space is provided ( 17) between the wall and the cylindrical element. 6. Device as stated in claim 5, characterized in that the cylindrical element (lh) is made of metal. Device as specified in any of claims 1-6), characterized in that the measuring device which is separate from said probe is provided with a heat-sensitive element with a low heat capacity designed to be placed in conductive contact with the probe, as well as means which provide a visual indication of the temperature the probe has assumed. 8. Device as stated in claim 7? characterized in that the measuring device consists of a weak current ammeter (10') with an electric circuit (22 - 28) which reacts to the temperature of the probe, the measuring device comprising means for temporarily holding the probe in a position that affects the aforementioned circle. 9. Device as stated in claim 7 or 8, characterized in that the heat-sensitive element is a rod-like thermistor (21), the tube-shaped end part (12) of the probe being adapted to fit over the thermistor in heat-conducting contact, and that the electric circuit (22 - 28) comprises means (3-1) for supplying electric current to it, and a switch (30) biased to the open position and designed to close when the probe (11) is brought into position above the tennis tor (21).