CN107773221B - Hand-held acupoint temperature detector - Google Patents

Abstract

The invention discloses a handheld acupoint temperature detector, which comprises a shell, wherein a heat insulation probe is movably arranged at the head of the shell and extends out of the head of the shell; an infrared temperature sensor is fixedly arranged in the heat insulation probe, a measuring channel is formed in the heat insulation probe to serve as a measuring window of the infrared temperature sensor, and the infrared temperature sensor can collect data through the measuring window of the heat insulation probe; the heat insulation probe is connected with one end of the reset spring, and the other end of the reset spring is connected with the inner end face of the shell; the return spring is used for resetting the insulated probe. According to the invention, the infrared temperature sensor is fixedly arranged in the heat insulation probe, and the heat insulation probe contacts with the acupoint to be measured during measurement, so that the distance between the infrared temperature sensor and the acupoint to be measured can be kept constant during measurement, thereby solving the influence of the measurement distance on the measurement precision of the infrared temperature sensor and improving the measurement precision of the instrument.

Description

Hand-held acupoint temperature detector

Technical Field

The invention relates to clinical detection equipment of traditional Chinese medicine, in particular to a handheld acupoint temperature detector.

Background

Acupoints, known as acupoints, refer to specific points on the meridian, and are used to treat diseases by stimulating corresponding points of the meridians by acupuncture, massage, acupoints pressing and moxibustion. Acupoints are proper nouns in traditional Chinese medicine, and are mostly the places with more nerve endings and blood vessels. The four kinds of points are generally classified into Jing point, jing external qi point, ayi point and Xuezhu point.

According to researches, the temperature of the acupoint is different from the temperature of the non-acupoint to a certain extent, and when a human body is ill, the temperature value of the corresponding acupoint changes, so that objective and quantitative data can be obtained under the non-invasive condition by monitoring the change trend of the temperature value of the acupoint, thereby directly reflecting the concept of cold and heat in traditional Chinese medicine and realizing the prevention or diagnosis of the disease.

However, how to accurately measure the temperature of the acupoints is a problem that is currently difficult to solve. The temperature of the acupuncture points is measured by measuring the body surface temperature of the acupuncture points, the area of the acupuncture points is smaller, the temperature difference between the temperature of the acupuncture points and the temperature of surrounding skin is only 0.5-1 ℃, and when the human body is ill, the temperature change of the corresponding acupuncture points is only about 0.5 ℃, so that the measurement accuracy is required to reach 0.01 ℃.

The most advanced body temperature measuring method at present is an ear temperature measuring method, the measuring principle is that a non-contact infrared temperature measuring technology is adopted, the measuring method has the advantages that the measuring time is long, the measuring can be completed within 1-2 seconds generally, the use is very convenient, but the measuring method has the defects that the measuring method can be influenced by the ambient temperature, the light intensity, the distance and the like, the measuring precision can only reach 0.1 ℃, and therefore the measuring method cannot be used for measuring the temperature of acupuncture points.

The theory of traditional Chinese medicine is formed in the period of war between spring and autumn, and the application has been carried out for more than two thousand years. However, since western medicine entered china, people began to question traditional Chinese medicine in the mode of thinking of the western medical system, even putting traditional Chinese medicine into debate between existence and disuse. One of the root causes is that the diagnosis result and effectiveness of traditional Chinese medicine are largely dependent on subjective judgment of doctors. How to make the diagnostic index of traditional Chinese medicine more objective and have diagnostic reference value is a break-through for the development of modern traditional Chinese medicine.

Disclosure of Invention

The invention aims to solve the technical problem of providing a handheld acupoint temperature detector which can accurately measure acupoint temperature and provide quantitative original data for doctors, thereby improving the accuracy of diagnosis of the doctors.

In order to solve the technical problems, the technical solution of the handheld acupoint temperature detector of the invention is as follows:

the device comprises a shell 1, wherein a heat insulation probe 7 is movably arranged at the head of the shell 1, and the heat insulation probe 7 extends out of the head of the shell 1; an infrared temperature sensor 6 is fixedly arranged in the heat insulation probe 7, a measuring channel is formed in the heat insulation probe 7 and used as a measuring window of the infrared temperature sensor 6, and the infrared temperature sensor 6 can collect data through the measuring window of the heat insulation probe 7; the heat insulation probe 7 is connected with one end of the return spring 9, and the other end of the return spring 9 is connected with the inner end face of the shell 1; the return spring 9 is used for resetting the adiabatic probe 7.

The handheld acupoint temperature detector has the technical effects that:

according to the invention, the infrared temperature sensor is fixedly arranged in the heat insulation probe, and the heat insulation probe contacts with the acupoint to be measured during measurement, so that the distance between the infrared temperature sensor and the acupoint to be measured (namely the measurement distance) can be kept constant during measurement, thereby solving the influence of the measurement distance on the measurement precision of the infrared temperature sensor and improving the measurement precision of the instrument.

According to the invention, the heat insulation probe contacts with the acupoint to be measured in the measuring process, and the measuring channel of the heat insulation probe can cover the temperature measuring point therein, so that the temperature measuring point is isolated from the external environment, a relatively airtight measuring environment can be created for the acupoint to be measured, the temperature of the acupoint to be measured is not influenced by the ambient temperature and the light intensity, and the measuring precision is further improved. It should be noted that, the operating condition of the present invention is different from that of the ear temperature detector, and the ear temperature detector also adopts a non-contact infrared temperature sensor, but the ear temperature detector collects the temperature of the tympanic membrane, and the tympanic membrane is located in the ear canal, so that the influence of the ambient temperature and the light intensity is small, while the acupoint to be detected is directly exposed to the body surface of the human body, the ambient temperature and the light intensity can cause the temperature change of the acupoint, and the present invention solves the influence of the ambient temperature and the light intensity on the acupoint temperature, so that the measurement accuracy is improved.

Further, the infrared temperature sensor 6 is provided with a positioning lug 6-1; the heat insulation probe 7 is provided with a temperature sensor positioning groove 7-1 along the axial direction, and the front end surface of the temperature sensor positioning groove 7-1 is used as a positioning surface of the positioning lug 6-1; the infrared temperature sensor 6 is fixedly connected with the heat insulation probe 7 through the matched connection of the positioning convex block 6-1 and the temperature sensor positioning groove 7-1. The infrared temperature sensor 6 belongs to a non-contact sensor, and although the measurement process does not need to contact a measurement point, the closer the infrared temperature sensor 6 is to the measurement point, the more accurate the measurement value is. According to the invention, the infrared temperature sensor 6 is fixedly connected with the heat insulation probe 7 through the matched connection of the positioning lug 6-1 and the temperature sensor positioning groove 7-1, and the distance between the infrared temperature sensor 6 and the stress end surface of the heat insulation probe 7 can be accurately controlled by changing the distance between the positioning surface of the temperature sensor positioning groove 7-1 and the stress end surface of the heat insulation probe 7, so that the infrared temperature sensor 6 is in the optimal measurement distance, and the measurement precision of the infrared temperature sensor 6 is improved.

Further, the infrared temperature sensor 6 is controlled by a photoelectric coupler 10-1. The essence of the control mode is that the switch and the switch are controlled by the moving distance of the infrared temperature sensor 6, and the moving distance of the infrared temperature sensor 6 is in direct proportion to the stress of the heat insulation probe 7, so that the control of the switch of the infrared temperature sensor 6 can be realized by controlling the stress of the heat insulation probe 7, and the operation is simpler and more convenient.

Preferably, the adiabatic probe 7 is fixedly connected with the photoelectric coupler 10-1, and the shell 1 is fixedly connected with the photoelectric coupler triggering piece 5-1 for triggering the photoelectric coupler 10-1; when the adiabatic probe 7 moves to the optical path of the photocoupler 10-1 to interfere with the photocoupler trigger piece 5-1, the infrared temperature sensor 6 is started.

Further, the infrared temperature sensor 6 is fixedly arranged at the front end of the photoelectric coupler control board 10; the photo-coupler 10-1 is fixedly arranged at the rear end of the photo-coupler control board 10.

Further, the heat insulating probe 7 is made of a heat insulating material. The heat insulation probe adopted by the invention is a heat bad conductor, and the heat insulation probe is in contact with the acupoint to be measured in the measuring process, but does not generate heat conduction, so the temperature change of the measured acupoint is not caused, the influence of heat conduction on the temperature is solved, the measured value of the acupoint temperature acquired by the temperature sensor is consistent with the true value, and the accuracy of the acquired data is ensured.

Further, a measurement elevation angle α is formed between the movement direction of the heat insulating probe 7 and the hand-held portion of the housing 1, and the measurement elevation angle α is in a range of 60±5 ℃, and the elevation angle in the range can facilitate the force application to the head of the housing 1 when the user holds the heat insulating probe.

Further, the return spring 9 is sleeved on the photoelectric coupler control board 10, so that the space utilization rate of the head of the shell 1 is improved.

Further, the head of the shell 1 is fixedly provided with a probe protecting sleeve 8, the heat insulation probe 7 is movably arranged in the probe protecting sleeve 8, and the heat insulation probe 7 extends out of the probe protecting sleeve 8. The probe protecting sleeve 8 can be fixedly connected with the shell 1 through a buckle structure, so that the probe protecting sleeve 8 is convenient to be fixedly connected with the shell 1.

The heat insulation probe 7 at the head of the shell 1 contacts with an acupoint to be tested, force is applied to the head of the shell 1, the force applied to the shell 1 acts on the heat insulation probe 7, the heat insulation probe 7 is stressed to compress the reset spring 9 to move backwards, and the heat insulation probe 7 drives the heat insulation probe to move backwards together with the fixedly connected photoelectric coupler 10-1; when the optical path of the photoelectric coupler 10-1 moved to the photoelectric coupler 10-1 interferes with the optical coupler triggering piece 5-1, the optical coupler triggering piece 5-1 cuts off the optical path of the photoelectric coupler 10-1, so that the photoelectric coupler 10-1 is triggered, the infrared temperature sensor 6 is started, and the infrared temperature sensor 6 collects temperature data from the acupoint to be detected through the measuring window of the heat insulation probe 7.

The invention has the following technical effects:

the invention adopts the non-contact infrared temperature sensor to realize contact temperature measurement, on one hand, fully utilizes the advantages of the non-contact infrared temperature sensor such as long measurement time and convenient use, and on the other hand, thoroughly solves the interference of heat conduction to the measured value in the contact temperature measurement process, and the interference of external conditions such as ambient temperature, light intensity and distance to the measured value, so that the measurement precision of the instrument reaches 0.01 ℃.

The invention organically combines modern science and technology with traditional Chinese medicine, can lead the acupoint temperature to be an objective index and an objective basis of doctor diagnosis, and provides a new thought for the traditional Chinese medicine diagnosis method, thereby greatly improving the accuracy of the traditional Chinese medicine diagnosis.

Drawings

It will be appreciated by those skilled in the art that the following description is merely illustrative of the principles of the invention, which can be applied in numerous ways to implement many different alternative embodiments. These descriptions are only intended to illustrate the general principles of the teachings of the present invention and are not meant to limit the inventive concepts disclosed herein.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the general description given above and the detailed description of the drawings given below, serve to explain the principles of the invention.

The invention is described in further detail below with reference to the attached drawings and detailed description:

FIG. 1 is a schematic cross-sectional view of a hand-held acupoint temperature sensor according to the present invention;

FIG. 2 is an exploded schematic view of the present invention;

FIG. 3 is another exploded schematic view of the present invention;

fig. 4 is a schematic view of a fixed block of the present invention.

The reference numerals in the drawings illustrate:

1 is a shell, 2 is a switch control board,

3 is a rear cover, 4 is a switch key,

5 is a fixed block, 6 is an infrared temperature sensor,

7 is an adiabatic probe, 8 is a probe protective sleeve,

9 is a return spring, 10 is a photoelectric coupler control board,

11 is a power supply box cover, 12 is a power supply,

5-1 is an optocoupler trigger piece, 6-1 is a positioning bump,

7-1 is a temperature sensor positioning groove, and 10-1 is a photoelectric coupler.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present invention fall within the protection scope of the present invention. Unless otherwise defined, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs. As used herein, the word "comprising" and the like means that elements or items preceding the word are included in the element or item listed after the word and equivalents thereof without precluding other elements or items. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "front", "rear", and the like are used only to indicate a relative positional relationship, and when the absolute position of the object to be described is changed, the relative positional relationship may be changed accordingly.

As shown in fig. 1 to 3, the handheld acupoint temperature detector comprises a shell 1, wherein a probe protective sleeve 8 is fixedly arranged on the head of the shell 1, an adiabatic probe 7 is movably arranged in the probe protective sleeve 8, and the adiabatic probe 7 extends out of the probe protective sleeve 8 on the head of the shell 1 so as to facilitate stress of the adiabatic probe 7;

an infrared temperature sensor 6 is fixedly arranged in the heat insulation probe 7, a measuring channel is formed in the heat insulation probe 7 and used as a measuring window of the infrared temperature sensor 6, and the infrared temperature sensor 6 can collect data through the measuring window of the heat insulation probe 7;

the heat insulation probe 7 is connected with one end of a return spring 9, the return spring 9 is sleeved on a photoelectric coupler control board 10, and the other end of the return spring 9 is connected with the inner end face of the shell 1;

the front end of the photoelectric coupler control board 10 is fixedly provided with an infrared temperature sensor 6; the infrared temperature sensor 6 is provided with a positioning lug 6-1; the heat insulation probe 7 is provided with a temperature sensor positioning groove 7-1 along the axial direction, and the front end surface of the temperature sensor positioning groove 7-1 is used as a positioning surface of the positioning lug 6-1; the infrared temperature sensor 6 is fixedly connected with the heat insulation probe 7 through the matched connection of the positioning convex block 6-1 and the temperature sensor positioning groove 7-1;

a fixed block 5 is fixedly arranged at the rear of the photoelectric coupler control board 10, and the fixed block 5 is fixedly connected with the shell 1;

the rear end of the photoelectric coupler control board 10 is fixedly provided with a photoelectric coupler 10-1, and an optical coupler trigger piece 5-1 for triggering the photoelectric coupler 10-1 is formed on the fixed block 5, as shown in fig. 4; the photoelectric coupler 10-1 is used for controlling the switch of the infrared temperature sensor 6;

the probe protective sleeve 8 is fixedly connected with the shell 1 through a buckle structure so as to facilitate the fixed connection between the probe protective sleeve 8 and the shell 1;

the shell 1 and the rear cover 3 form an inner cavity of the shell 1; the shell 1 and the rear cover 3 are fixedly connected through a buckle connection;

the shell 1 and the power box cover 11 form a power box, and the power box is used for accommodating a power supply 12; the shell 1 is fixedly connected with the power box cover 11 through a buckle connection;

a switch control board 2 is fixedly arranged in the shell 1, the switch control board 2 is connected with a switch key 4, and the switch key 4 is used for controlling the on-off of a circuit of the instrument;

the heat insulating probe 7 is made of a heat insulating material.

A measurement elevation angle alpha is formed between the movement direction of the heat insulation probe 7 and the hand-held part of the shell 1; in consideration of ergonomics and experience of a measured person, the range of the measurement elevation angle α is 60±5 ℃, and the elevation angle in this range can facilitate the application of force to the head of the housing 1 when the user holds the hand.

The working principle of the invention is as follows:

the switch key 4 is opened to enable the instrument to be in a working state, the hand-held part of the shell 1 is held by hand, the heat insulation probe 7 at the head of the shell 1 is enabled to contact an acupoint to be tested, force is applied to the head of the shell 1, the force applied to the shell 1 acts on the heat insulation probe 7, the heat insulation probe 7 is stressed to compress the reset spring 9 to move backwards, and the heat insulation probe 7 drives the heat insulation probe 7 to move backwards together with the fixedly connected photoelectric coupler control board 10, so that the photoelectric coupler 10-1 is driven to move backwards; when the optical path of the photoelectric coupler 10-1 moves back to the photoelectric coupler 10-1 and interferes with the optical coupler triggering piece 5-1, the optical coupler triggering piece 5-1 cuts off the optical path of the photoelectric coupler 10-1 so as to trigger the photoelectric coupler 10-1, the infrared temperature sensor 6 is started, and the infrared temperature sensor 6 collects temperature data from the acupoint to be detected through the measuring window of the heat insulation probe 7;

after the detection is finished, the heat insulation probe 7 at the head of the shell 1 is separated from the acupoint to be detected, and the heat insulation probe 7 automatically resets under the action of the reset spring 9.

The infrared temperature sensor 6 belongs to a non-contact sensor, and although the measurement process does not need to contact a measurement point, the closer the infrared temperature sensor 6 is to the measurement point, the more accurate the measurement value is. According to the invention, the positioning lug 6-1 is connected with the temperature sensor positioning groove 7-1 which is stopped at the head of the heat insulation probe 7 in a matched manner, so that the distance between the infrared temperature sensor 6 and the stressed end face of the heat insulation probe 7 can be controlled, and the distance between the infrared temperature sensor 6 and the acupoint to be detected can be accurately controlled.

According to the invention, the infrared temperature sensor 6 is arranged in the heat insulation probe 7, and when the heat insulation probe 7 contacts with the acupoint to be measured during measurement, the infrared temperature sensor 6 is at the optimal measurement distance, so that the measurement accuracy can be improved.

While embodiments of the present invention have been described in detail hereinabove, it will be apparent to those skilled in the art that various modifications and variations can be made to these embodiments. It is to be understood that such modifications and variations are within the scope and spirit of the present invention as set forth in the following claims. Moreover, the invention described herein is capable of other embodiments and of being practiced or of being carried out in various ways.

Claims (7)

1. A handheld acupuncture point temperature detector which is characterized in that: comprises a shell (1), wherein the head of the shell (1) is movably provided with an adiabatic probe (7), and the adiabatic probe (7) extends out of the head of the shell (1);

an infrared temperature sensor (6) is fixedly arranged in the heat insulation probe (7), a measuring channel is formed in the heat insulation probe (7) and used as a measuring window of the infrared temperature sensor (6), and the infrared temperature sensor (6) can collect data through the measuring window of the heat insulation probe (7);

the heat insulation probe (7) is connected with one end of the return spring (9), and the other end of the return spring (9) is connected with the inner end surface of the shell (1); the return spring (9) is used for resetting the heat insulation probe (7);

the infrared temperature sensor (6) is provided with a positioning lug (6-1); the heat insulation probe (7) is provided with a temperature sensor positioning groove (7-1) along the axial direction, and the front end surface of the temperature sensor positioning groove (7-1) is used as a positioning surface of the positioning lug (6-1); the infrared temperature sensor (6) is fixedly connected with the heat insulation probe (7) through the matching connection of the positioning convex blocks (6-1) and the temperature sensor positioning grooves (7-1);

the infrared temperature sensor (6) is controlled through a photoelectric coupler (10-1);

the heat insulation probe (7) is fixedly connected with the photoelectric coupler (10-1), and the shell (1) is fixedly connected with the photoelectric coupler triggering piece (5-1) for triggering the photoelectric coupler (10-1); when the light path from the adiabatic probe (7) to the photoelectric coupler (10-1) interferes with the photoelectric coupler trigger piece (5-1), the infrared temperature sensor (6) is started.

2. The hand-held acupoint temperature sensor of claim 1, wherein: the infrared temperature sensor (6) is fixedly arranged at the front end of the photoelectric coupler control board (10); the photoelectric coupler (10-1) is fixedly arranged at the rear end of the photoelectric coupler control board (10).

3. The hand-held acupoint temperature sensor of claim 1, wherein: the heat insulation probe (7) is made of heat insulation materials.

4. The hand-held acupoint temperature sensor of claim 1, wherein: a measurement elevation angle (alpha) is formed between the movement direction of the heat insulation probe (7) and the handheld part of the shell (1), and the range of the measurement elevation angle (alpha) is 60+/-5 ℃.

5. The hand-held acupoint temperature sensor of claim 2, wherein: the reset spring (9) is sleeved on the photoelectric coupler control board (10).

6. The hand-held acupoint temperature sensor of claim 1, wherein: the head of the shell (1) is fixedly provided with a probe protective sleeve (8), the heat insulation probe (7) is movably arranged in the probe protective sleeve (8), and the heat insulation probe (7) extends out of the probe protective sleeve (8).

7. The hand-held acupoint temperature sensor of claim 1, wherein: the heat insulation probe (7) at the head of the shell (1) contacts with an acupoint to be tested, force is applied to the head of the shell (1), the force applied to the shell (1) acts on the heat insulation probe (7), the heat insulation probe (7) is stressed to compress the return spring (9) to move backwards, and the heat insulation probe (7) drives the heat insulation probe to move backwards together with the fixedly connected photoelectric coupler (10-1); when the optical path of the photoelectric coupler (10-1) moves backwards to the photoelectric coupler (10-1) and interferes with the photoelectric coupler trigger piece (5-1), the photoelectric coupler trigger piece (5-1) cuts off the optical path of the photoelectric coupler (10-1) so as to trigger the photoelectric coupler (10-1), the infrared temperature sensor (6) is started, and the infrared temperature sensor (6) collects temperature data from an acupoint to be detected through a measurement window of the heat insulation probe (7).