CN201917404U - Body temperature measuring device - Google Patents

Abstract

The utility model discloses a body temperature detecting device, comprising a probe body, wherein the probe body is a hollow cavity body in which a temperature sensor is arranged, and the temperature sensor and the insulation in the probe body are bonded together. A probe adopts a hollow thin-walled structure, on the premise that the shape and the volume of the traditional body temperature probe are not changed, material use is greatly decreased, the heat capacity of the probe is greatly reduced, and the time needed for renewed heat balance is greatly reduced. In addition, metal accounts for more than half of the materials used by the probe, a metal shell body can be regarded as an isothermal body, and probe can sensitively change according to the temperature changes of a surface microstructure. An epoxy resin with good heat conductivity is adopted to cause that the temperature sensor and the metal shell body are bonded together, the heat resistance from the metal shell body to the sensor is greatly reduced, therefore the probe can realize heat balance very quickly, and response speed is greatly quickened.

Description

Body temperature measuring device

Technical field

The utility model relates to a kind of temperature measuring equipment, particularly relates to the measurement mechanism that is used to measure the body surface temperature.

Background technology

Body surface body temperature probe is mainly used in the continuity temperature check in monitoring or the operation, and it is mainly by the heat conductive metal dish, and the epoxy resin of temperature sensor, connection lead and encapsulation probe is formed.

When body surface body temperature probe used in flat parts such as arm necks, as Fig. 1, the probe metal covering adhere well to body surface organization, and the back generally can cover a little gauzes and so on heat-barrier material, fixes with adhesive tape then.Because heat-barrier material has extremely low thermal conductivity, so can think and be heat guard.Heat conducts to the probe metal dish by body surface organization in this use pattern, and by deep tissues with body surface organization's additional heat with thermal equilibrium again.The route that arrow indication expression hot-fluid among the figure transmits, what at first be heated as can be seen is metal dish, is conducted heat to epoxy resin by metal dish then, at last heating temperature sensor wherein.

When body surface body temperature probe uses at narrow and small positions such as armpits, as shown in Figure 2, this moment probe is held by body surface organization is two-sided, can assert that it two-sidedly is subjected to tissue heat transfer, the route that arrow indication expression hot-fluid among the figure transmits, the body surface organization on both sides is again with deep tissues thermal equilibrium.The epoxy resin at Zheng Mian metal dish and back is heated simultaneously like this, because metal is thinner, thermal capacitance is lower, so the metal dish after being heated continues the epoxy resin of heating poor heat conductivity, temperature sensor is heated.

In two kinds of environments for use, the factor that influences temperature sensor response speed mainly contains 2 points.The one, after the body surface organizes the heat conduction cooling, with the thermally equilibrated again speed of deep tissues.The principal ingredient of tissue is an aqueous water, is limited but mostly cut apart, and is mobile very poor, because water is that specific heat capacity is very big, and poor heat conduction, so heat conduction is slow in the tissue.This response speed to the body temperature probe has constituted main influence, and the key that determines its degree is the required heat of balance, and the leading factor of this point is the thermal capacity of probe usually.Another point is for after itself being heated in the probe, and integral body reaches thermally equilibrated speed.Wherein metal has high temperature conductivity (be tens the order of magnitude), and promptly hot-fluid is very fast in the metal, and can look metal dish substantially is isothermal body.And the temperature conductivity of epoxy resin lower (about 1), and consumption is more, thick partially in the existing probe, makes hot-fluid all relatively slowly, and this directly causes existing probe overall thermal balance slow.Be exactly these 2 response speeds that have a strong impact on body surface body temperature probe.According to clinical trial, probe generally needed 5 minutes even tens of minutes just can reach thermal equilibrium.

Current, multinomial patent at lifting body temperature measuring device response speed is arranged, use the sub warhead of rear end thermal insulation to pop one's head in as patent CN02150330.3, and thin wire is sticked on the metallic walls.And patent CN200420088054.X uses adiabatic expanded material to fill probe.But these patents only relate to be applicable to the electronic thermometer of a survey, do not relate to the body surface body temperature probe that is applicable to that continuity is measured.

The utility model content

Problem to be solved in the utility model is to overcome deficiencies such as prior art body temperature probe high heat capacity, low heat conduction; Thereby a kind of low heat capacity, high heat conduction are provided, respond body surface measurement of bldy temperature fast.

The utility model is by the following technical solutions to achieve these goals:

A kind of body temperature sniffer comprises the probe body, and described probe body is a hollow cavity, in this hollow cavity temperature sensor is set, after this temperature sensor is bonded into one with probe body inboard, and temperature sensor and the inboard insulation of probe body.

The probe body is combined by two metal dish, covers epoxy resin on the metal dish therein, and epoxy resin is bonding with metal dish and temperature sensor.

The probe body can be mounted to by two metal dish up and down, wherein descends between metal dish and the temperature sensor heat-conductive bonding agent is set, and following metal dish is bonding through heat-conductive bonding agent and temperature sensor.

Heat-conductive bonding agent in the utility model is the heat-conductive bonding agent of insulation.

The probe body is provided with a through hole, leads line and passes the through hole of probe on the body and be electrically connected with temperature sensor.

Metal dish utilizes buckle to install up and down, and is provided with gluingly in metal dish junction up and down, makes that installing and fixing back probe body is a cavity.

After metal dish can adopt welding fixing up and down, make that installing and fixing back probe body is a cavity.

At through hole and lead filling epoxy resin between the line.

Heat-conductive bonding agent in the utility model is epoxy resin.

The method for making of the utility model body temperature sniffer is, at first the metal probe body is arranged to the cavity of a hollow, and will with lead the temperature sensor that line is connected and insert in this cavity, the heat-conductive bonding agent that utilizes the loop-like epoxy resins again is bonded in the inwall of cavity with temperature sensor, and the body temperature sniffer is made and finished.

The utility model is compared with the probe that existing metal dish applies a large amount of epoxy encapsulation, probe adopts the hollow and thin-walled structure, under the prerequisite that does not change traditional body temperature probe shape and volume, significantly reduced the material use, make the thermal capacity of probe reduce greatly, the required time of thermal equilibrium again of body surface and deep tissues is reduced greatly.Popping one's head in addition, metal accounts for exhausted vast scale in the material therefor, based on the characteristic of metal, makes metal shell can think isothermal body, and it can the responsive temperature variation of following textura epidermoidea.Adopt again thermal conductivity preferably epoxy resin make temperature sensor and metal shell bonding, metal shell reduces greatly to the thermal resistance of sensor, makes the probe can very fast realization thermal equilibrium, has accelerated response speed greatly.

Description of drawings

Fig. 1 is the hot-fluid synoptic diagram of existing probe at body surface measurement;

The hot-fluid synoptic diagram that Fig. 2 measures at armpit for existing probe;

Fig. 3 is the appearance assumption diagram of the utility model probe;

Fig. 4 for the utility model probe along A-A to cut-open view,

Fig. 5 for the utility model probe along B-B to cut-open view;

Fig. 6 is the hot-fluid synoptic diagram of the utility model probe at body surface measurement;

The hot-fluid synoptic diagram that Fig. 7 measures at armpit for the utility model probe;

Fig. 8 is that the utility model contrasts with the heating curve under the environment with existing probe.

Embodiment

Be further described below in conjunction with the most preferred embodiment shown in the accompanying drawing.

, comprise tabular thin-walled probe body 5, epoxy resin 6, temperature sensor 3 and lead line 4 to the utility model body temperature sniffer shown in Figure 5 as Fig. 3.The body 5 of at first will popping one's head in is arranged to the cavity of hollow, will insert in the cavity of hollows with leading the temperature sensor 3 that line 4 is connected, and utilizes small amount of epoxy resin 6 that temperature sensor 3 is bonded in the inwall of cavity again,

The probe body 5 of hollow form wherein is a metal shell, can use coefficient of heat conductivity height such as stainless steel, tinned copper, the metal material of good mechanical property, and physical dimension and existing complete probe are similar, and its chamber wall is thinner, about 0.2mm, outward appearance is bright and clean, no burr slit.All the other sealings except that the side is the perforate reserved of line.Can be global formation, also can process each several part in advance respectively, the later stage be combined as integral body by modes such as welding, glue envelopes.

Probe body 5 in the present embodiment is combined into by a U-shaped metal dish and cover, the U-shaped metal dish possesses the cavity of a hollow, reserve through hole on the cavity and be used to lead passing through of line 4, apply micro-epoxy resin 6 in the U-shaped metal dish, this epoxy resin 6 has characteristics such as the good and insulation of thermal conductivity; To lead line 4 then passes U-shaped metal dish side perforate and introduces down the U-shaped metal dish and weld with temperature sensor 3, and make temperature sensor 3 and lead and chamber wall keep apart certain distance, make evenly parcel (can certainly suitably increase epoxy resin 6 consumptions makes it can adhere to cover and U-shaped metal dish simultaneously) of U-shaped metal dish inwall and temperature sensor 3 bonding backs with epoxy resin 6 again.At last cover and U-shaped metal dish are closed up and be welded as integral body; Certainly also can also use snap fit and in conjunction with gluing its fixing seal that makes.The through hole of while on probe body 5 and the gap filling epoxy resin 6 of leading line 4.

Wherein the characteristic of epoxy resin 6 can make probe body 5 and metering circuit insulate.If high-voltage occurs in the circuit, can suitably increase the insulation distance of sensor 3 and betal can 5.

As Fig. 6, when probe is measured at smooth tissue place, the heat-insulation layer of back covering one deck gauze 1 and so on and since thermal conductivity extremely low, can think that it is a heat guard.During measurement, rapid and tight probe body 5 equilibrium temperatures that contact of textura epidermoidea, heat flows into probe rapidly, textura epidermoidea's loses heat, this moment, deep tissues began to conduct heat to textura epidermoidea, promptly conducted heat in the tissue, because the probe thermal capacitance is very low, the amount of hot-fluid is little a lot, and the speed that makes can be accelerated greatly.The probe body 5 of metal has high temperature conductivity simultaneously, make hot-fluid very fast (arrow among the figure is represented route and the direction that hot-fluid transmits) in the metal, substantially can think that whole probe body 5 is isothermal body, hot-fluid is that heat is flowed to temperature sensor 3 by epoxy resin 6 by probe body 5, because content of epoxy resin is few, and thickness as thin as a wafer, so the hot-fluid in the existing probe is a lot of soon.Body 5 pop one's head in simultaneously also by intracavity gas and 3 heat conduction of radiation direction temperature sensor, improved the response speed of temperature sensor 3 greatly.

As Fig. 7, when popping one's head at area measures such as armpits, owing to be two-sided being heated, both sides are organized and interior hot-fluid all can be occurred organizing like this, and (arrow among the figure is represented route and the direction that hot-fluid transmits) makes and organize thermal equilibrium speed further to promote.Thereby the heat of probe body 5 flow into to be increased, make that the rate of heat flow of air is accelerated simultaneously in hot-fluid in the epoxy resin 6 and the chamber, make the response of temperature sensor 3 rapider.

As Fig. 8, this is under the equivalent environment, and the utility model probe contrasts with the heating curve of existing probe, and the heating curve of the utility model probe obviously is better than existing body temperature probe as can be seen.Heat up slowly during the test of tradition body temperature probe, approximately needed 5 minutes just can reach 36 ℃.And the utility model probe as figure are only with just reaching 36 ℃ second surplus 70.Reaching the balance time spent shortens greatly.Reached the effect of quick response.

Claims (8)

1. a body temperature sniffer comprises the probe body, it is characterized in that: described probe body is a hollow cavity, in this hollow cavity temperature sensor is set, and temperature sensor is bonded into one with the inboard insulation of probe body.

2. a kind of body temperature sniffer according to claim 1 is characterized in that: described probe body is combined by two metal dish, therein tack temperature sensor on the metal dish.

3. a kind of body temperature sniffer according to claim 2, it is characterized in that: described probe body is mounted to by two metal dish up and down, wherein descend between metal dish and the temperature sensor heat-conductive bonding agent is set, following metal dish is bonding through heat-conductive bonding agent and temperature sensor.

4. a kind of body temperature sniffer according to claim 3 is characterized in that: described heat-conductive bonding agent is the heat-conductive bonding agent of insulation.

5. a kind of body temperature sniffer according to claim 3 is characterized in that: described probe body is provided with a through hole, leads line and passes the through hole of probe on the body and be electrically connected with temperature sensor.

6. a kind of body temperature sniffer according to claim 5 is characterized in that: described through hole and lead filling epoxy resin between the line.

7. a kind of body temperature sniffer according to claim 3 is characterized in that: described up and down metal dish buckle is installed, and is provided with in metal dish junction up and down and gluingly makes that to install and fix back probe body be a cavity.

8. a kind of body temperature sniffer according to claim 3 is characterized in that: the metal dish welding is fixing up and down, and making and installing and fixing back probe body is a cavity.

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