CN219353888U - Electrocardiogram and body temperature two-in-one measuring structure and device - Google Patents

Abstract

The utility model discloses an electrocardio-body temperature two-in-one measuring structure and a device thereof. When the electrocardio-body temperature two-in-one measuring structure is adopted for collecting human body information of a patient, the metal sheet is attached to a measured object, heat of the measured object is transmitted to the temperature sensing device through the heat conductor to measure temperature, and the metal buckle is buckled on the electrocardio-electrode sheet and collects electrocardio signals of the measured object. Therefore, the electrocardiosignal and body temperature integrated measurement structure with dual functions of electrocardiosignal and body temperature detection is integrated, medical staff do not need to wear different measurement accessories respectively, and only one measurement structure is needed to be worn to complete electrocardiosignal and body temperature detection, so that the electrocardiosignal and body temperature integrated measurement structure has the advantages of convenience in wearing, convenience in operation and the like. Meanwhile, as the number of accessories is one, the steps of taking out and withdrawing the other accessory are reduced, and the steps of detecting the electrocardiosignals and the body temperature of a patient by medical staff are simplified.

Description

Electrocardiogram and body temperature two-in-one measuring structure and device

Technical Field

The utility model relates to the technical field of measuring instruments, in particular to an electrocardio-body temperature two-in-one measuring structure and device.

Background

At present, two sets of measurement accessories are used for monitoring electrocardio and body temperature of a clinical patient, so that a nurse needs to prepare two sets of measurement accessories when carrying out human body information measurement on the patient, and if any measurement accessory is missed during detection, the nurse needs to go to a corresponding accessory room again to take, and the detection efficiency is greatly reduced. Meanwhile, in the operation process, nurses often install the electrocardio accessory first and then install the body temperature accessory, are in split design based on two sets of measurement accessories, and are often prone to causing technical problems of being unfavorable for operation and complex in operation in the bedside environment of patients.

Accordingly, the prior art is in need of improvement.

Disclosure of Invention

The utility model mainly aims to provide an electrocardio-body temperature two-in-one measuring structure and device, which at least solve the technical problem that the human body information of a patient is unfavorable for operation in the related technology.

The utility model provides an electrocardio-body temperature two-in-one measuring structure, which comprises a shell, a metal sheet, a heat conductor, a temperature sensing device and a metal buckle, wherein the shell is arranged on the shell;

the shell is provided with a through cavity, the metal sheet is arranged on one side of the through cavity, the metal buckle is arranged on the other side of the through cavity opposite to the side where the metal sheet is arranged, the heat conductor is arranged in the through cavity and is positioned between the metal sheet and the metal buckle, and the temperature sensing device is arranged in the heat conductor;

the metal sheet is used for being attached to a measured object and transmitting heat of the measured object to the temperature sensing device through the heat conductor, the temperature sensing device is used for detecting the body temperature of the measured object, and the metal buckle is used for being buckled on the electrocardio-electrode sheet and collecting electrocardio-signals of the measured object.

In a second aspect of the present utility model, a measurement device is provided, which is characterized by comprising an electrocardiograph electrode plate and the electrocardiograph body temperature two-in-one measurement structure of the first aspect, wherein the electrocardiograph electrode plate is connected with the electrocardiograph body temperature two-in-one measurement structure.

The utility model relates to an electrocardio-body temperature two-in-one measuring structure and a device, which are formed by a shell, a metal sheet, a heat conductor, a temperature sensing device and a metal buckle. When the electrocardio-body temperature two-in-one measuring structure is adopted to collect human body information of a patient, the metal sheet is attached to the measured object, heat of the measured object is transmitted to the temperature sensing device through the heat conductor to measure temperature, and the metal buckle is buckled on the electrocardio-electrode sheet to collect electrocardio signals of the measured object. Therefore, the electrocardiosignal and body temperature integrated measurement structure with dual functions of electrocardiosignal and body temperature detection is integrated, medical staff do not need to wear different measurement accessories respectively, and only one measurement structure is needed to be worn to complete electrocardiosignal and body temperature detection, so that the electrocardiosignal and body temperature integrated measurement structure has the advantages of convenience in wearing, convenience in operation and the like. Meanwhile, as the number of accessories is one, the steps of taking out and withdrawing the other accessory are reduced, and the steps of detecting the electrocardiosignals and the body temperature of a patient by medical staff are simplified.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a cross-sectional view of a housing of a two-in-one core electric body temperature measurement structure according to an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of a two-in-one measurement structure for temperature of a center electrode according to an embodiment of the present utility model;

fig. 3 is a three-dimensional schematic diagram of a two-in-one measurement structure for central electric body temperature according to an embodiment of the present utility model.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It is noted that related terms such as "first," "second," and the like may be used to describe various components, but these terms are not limiting of the components. These terms are only used to distinguish one element from another element. For example, a first component could be termed a second component, and, similarly, a second component could be termed a first component, without departing from the scope of the present utility model.

Referring to fig. 1, 2 and 3, the two-in-one electrocardiograph and body temperature measuring structure provided by the present utility model includes a housing 10, a metal sheet 20, a heat conductor 50, a temperature sensing device 40 and a metal button 30.

The housing 10 may be a structure made of plastic, ensuring a certain portability and strength. Generally, a through cavity 10A is formed, and the through cavity 10A penetrates through the upper end face and the lower end face of the casing 10 to play a role in placing other devices.

The metal sheet 20 may be a sheet-like structure having a good heat conductive property and a high hardness, such as an aluminum sheet; it mainly contacts with the skin of the tested object to conduct the heat of the tested object primarily. Generally, it is disposed at one side of the through cavity 10A, and the metal button 30 is disposed at the other side of the through cavity 10A opposite to the side of the metal sheet 20; that is, when the metal sheet 20 is disposed on one side of the through cavity 10A near the top, the corresponding metal button 30 is disposed on the other side of the through cavity 10A near the bottom.

The heat conductor 50 may be a structure with better heat conducting property, such as epoxy resin; typically, it is disposed within the through cavity 10A between the metal sheet 20 and the metal button 30, and the heat conductor 50 is provided with a temperature sensing device 40. Thus, the heat conductor can further conduct the heat conducted by the metal sheet 20 from the object to be measured to the temperature sensing device 40 on the heat conductor 50.

The temperature sensing device 40 may be a device capable of sensing, detecting temperature, such as a thermistor or a temperature sensor; generally, the temperature sensing device 40 is disposed at a central position of the heat conductor 50, so as to accurately detect the body temperature corresponding to the measured object through the heat on the heat conductor 50. When the temperature sensing device 40 selects the thermistor, the thermistor can be connected with a resistor detection circuit, an AD conversion circuit and a display screen, so as to accurately measure the body temperature of the measured object.

When the technical scheme is implemented, namely, when the electrocardio-body temperature two-in-one measuring structure is adopted to collect human body information of a patient, the metal sheet is attached to the temperature sensing part of the measured object, then the heat of the measured object is transmitted to the temperature sensing device through the heat conductor to measure the temperature, and meanwhile, the metal buckle is buckled on the electrocardio-electrode sheet and collects electrocardio signals of the measured object. Therefore, the electrocardiosignal and body temperature integrated measurement structure with dual functions of electrocardiosignal and body temperature detection is integrated, medical staff do not need to wear different measurement accessories respectively, and only one measurement structure is needed to be worn to complete electrocardiosignal and body temperature detection, so that the electrocardiosignal and body temperature integrated measurement structure has the advantages of convenience in wearing, convenience in operation and the like. Meanwhile, as the number of accessories is one, the steps of taking out and withdrawing the other accessory are reduced, and the steps of detecting the electrocardiosignals and the body temperature of a patient by medical staff are simplified.

In some alternative implementations of this embodiment, the housing 10 includes an outer mold 100 and an inner frame 110, the outer mold 100 providing a layer of protection and the inner frame 110 providing a layer of protection, the two layers being stacked to increase the rigidity of the housing 10, further protecting the devices disposed in the through cavity 10A. And the inner skeleton 110 is sleeved in the outer die body 100 and forms a through cavity 10A, that is, the inner wall of a part of the inner skeleton 110 and the inner wall of a part of the outer die body 100 together form a cavity wall of the through cavity 10A, so that the formed two inner walls together serve as a protection layer of each device in the through cavity 10A.

Wherein, the penetrating direction of the through cavity 10A is vertical to the axial direction of the inner skeleton 110; by defining the penetration direction of the through-cavity 10A, the difficulty in assembling each device in the through-cavity 10A can be effectively reduced by fitting the inner frame 110 having a bar shape.

In some alternative implementations of the present embodiment, the outer mold 100 has a first end face 100B and a second end face 100A disposed opposite to each other, the through cavity 10A is located between the first end face 100B and the second end face 100A, and a contact portion of the metal sheet 20 for contacting the object to be measured protrudes outward relative to the first end face 100B; the skin of the measured object is better contacted by the relatively convex contact part on the metal sheet 20, which is beneficial to the conduction of the body temperature. At the same time, the relatively convex contact portion can also serve as a macroscopic "sign" to facilitate guiding the medical staff to contact the contact portion on the metal sheet 20 with the area that most accurately reflects the body temperature of the subject (patient).

The contact portion has at least one end surface parallel to the axial direction of the inner skeleton, so that the contact portion of the metal sheet 20 and the skin of the measured object show a contact relationship, and the stability of heat transfer from the measured object to the metal sheet in the body temperature measurement process is ensured.

In some alternative implementations of this embodiment, the top of the heat conductor 50 is secured to the bottom of the metal sheet 20 by at least one layer of heat conductive glue, and the bottom of the heat conductor 50 is secured to the top of the metal button by at least one layer of heat insulating glue; that is, in the assembly process, the top of the heat conductor 50 and the bottom of the metal sheet 20 are bonded by at least one layer of heat conducting glue, so that the heat conducting efficiency of the two is improved. Meanwhile, at least one layer of heat insulation glue is utilized to fix the bottom of the heat conductor 50 with the top of the metal buckle 30, so that the influence of heat on the heat conductor 50 on heating and the like caused by the metal buckle is avoided.

Wherein the ratio of the surface area of contact between the top of the heat conductor 50 and the heat conductive paste to the surface area of contact between the bottom of the metal sheet 20 and the heat conductive paste is 0.8-1.2; i.e. to ensure that the surface area between the two closely spaced contact surfaces between the metal sheet 20 and the heat conductor 50 is substantially the same, thereby ensuring the accuracy of the heat transfer.

Wherein, the center of the heat conductor 50 is provided with an inner hole, the temperature sensing devices 40 are distributed annularly along the wall of the inner hole, and accordingly, the heat temperatures of the plurality of positions on the heat conductor 50 are detected by the plurality of temperature sensing devices 40, so that the heat temperature with the largest occurrence number can be selectively used as the detected temperature.

The embodiment also provides a measuring device, which comprises an electrocardio electrode plate and the electrocardio-body temperature two-in-one measuring structure of the embodiment, wherein the electrocardio electrode plate is connected with the electrocardio-body temperature two-in-one measuring structure.

Through the measuring device, when human body information of a patient is acquired, the metal sheet is attached to the measured object, heat of the measured object is transmitted to the temperature sensing device through the heat conductor to measure the temperature, and the metal buckle is buckled on the electrocardio-electrode sheet and acquires electrocardio-signals of the measured object. Therefore, the electrocardiosignal and body temperature integrated measurement structure with dual functions of electrocardiosignal and body temperature detection is integrated, medical staff do not need to wear different measurement accessories respectively, and only one measurement structure is needed to be worn to complete electrocardiosignal and body temperature detection, so that the electrocardiosignal and body temperature integrated measurement structure has the advantages of convenience in wearing, convenience in operation and the like. Meanwhile, as the number of accessories is one, the steps of taking out and withdrawing the other accessory are reduced, and the steps of detecting the electrocardiosignals and the body temperature of a patient by medical staff are simplified.

The foregoing description is only of the preferred embodiments of the present utility model, and is not intended to limit the scope of the utility model, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (10)

1. The electrocardio-body temperature two-in-one measuring structure is characterized by comprising a shell, a metal sheet, a heat conductor, a temperature sensing device and a metal buckle;

the shell is provided with a through cavity, the metal sheet is arranged on one side of the through cavity, the metal buckle is arranged on the other side of the through cavity opposite to the side where the metal sheet is arranged, the heat conductor is arranged in the through cavity and is positioned between the metal sheet and the metal buckle, and the temperature sensing device is arranged in the heat conductor;

the metal sheet is used for being attached to a measured object and transmitting heat of the measured object to the temperature sensing device through the heat conductor, the temperature sensing device is used for detecting the body temperature of the measured object, and the metal buckle is used for being buckled on the electrocardio-electrode sheet and collecting electrocardio-signals of the measured object.

2. The two-in-one electrocardiograph and body temperature measurement structure according to claim 1, wherein the shell comprises an outer die body and an inner framework;

the inner framework is sleeved in the outer die body and forms the through cavity.

3. The two-in-one electrocardiograph body temperature measurement structure according to claim 2, wherein the outer die body is provided with a first end face and a second end face which are oppositely arranged, the through cavity is positioned between the first end face and the second end face, and a contact part on the metal sheet for contacting with the measured object protrudes outwards relative to the first end face.

4. The two-in-one electrocardiograph structure according to claim 3, wherein the contact portion has at least one end surface parallel to the axial direction of the inner skeleton.

5. The two-in-one electrocardiograph body temperature measurement structure according to claim 1, wherein the top of the heat conductor is fixed with the bottom of the metal sheet through at least one layer of heat conducting glue, and the bottom of the heat conductor is fixed with the top of the metal buckle through at least one layer of heat insulating glue.

6. The two-in-one electrocardiograph body temperature measurement structure according to claim 5, wherein a ratio of a surface area of contact between the top of the heat conductor and the heat conductive adhesive to a surface area of contact between the bottom of the metal sheet and the heat conductive adhesive is 0.8-1.2.

7. The two-in-one electrocardiographic and body temperature measurement structure according to claim 1, wherein the heat conductor is epoxy resin.

8. The two-in-one electrocardiograph and body temperature measurement structure according to claim 1, wherein the temperature sensing device is a thermistor.

9. The electrocardio-body temperature two-in-one measuring structure of claim 1, wherein an inner hole is formed in the central position of the heat conductor, and the plurality of temperature sensing devices are distributed annularly along the wall of the inner hole.

10. A measuring device, comprising an electrocardiograph electrode sheet and the electrocardiograph and body temperature two-in-one measuring structure according to any one of claims 1 to 9, wherein the electrocardiograph electrode sheet is connected with the electrocardiograph and body temperature two-in-one measuring structure.