CN209751022U - Pulse feeling device and pulse feeling finger sleeve - Google Patents

Abstract

The utility model relates to a pulse feeling device and a pulse feeling finger sleeve, which comprises a sleeve body and a force sensor module. The cover body is used for being sleeved on the end part of the finger. The force sensor module is arranged at one end of the sleeve body, and after the sleeve body is sleeved on the end part of the finger, the force sensor module is in direct contact fit or indirect contact fit with the end surface of the finger. When the pulse feeling finger sleeve is used, the force sensor module is contacted with the cun pulse, guan pulse or chi pulse on the wrist, and the force sensor module can correspondingly acquire the pulse condition information of the cun pulse, guan pulse or chi pulse and send the pulse condition information to the host equipment for analysis and storage processing. In addition, the end of the finger can synchronously sense pulse condition information of cun pulse, guan pulse or chi pulse when contacting the force sensor module. Therefore, the manual pulse taking and the force sensor module are integrated, so that the standardized pulse taking can be realized no matter a doctor uses or a common user uses, the pulse feeling data can be used for back-end analysis, and the accuracy of the pulse feeling data can be improved.

Description

Pulse feeling device and pulse feeling finger sleeve

Technical Field

The utility model relates to the technical field of medical equipment, in particular to a pulse feeling device and a pulse feeling finger sleeve.

Background

Inspection, auscultation, inquiry and inquiry are four important means of traditional Chinese medicine diagnosis in China. Among them, the "cut" is an essential part of the diagnostic process. The accumulation of the experience of the elder generation can classify the pulse conditions into many categories, such as floating pulse, deep pulse, excessive pulse, deficient pulse, etc. The traditional Chinese medical diagnosis of pulse condition usually depends on the experience of doctor of traditional Chinese medical science to take charge of analysis, and different doctors may have different hand feeling when seeing the same pulse condition. At present, the force sensor of the pulse feeling device is used to sense and acquire the pulse condition information of the cun, guan and chi parts, i.e. the pulse feeling device is used to acquire the pulse condition information. However, the data information collected by the pulse diagnosis device may be abnormal, resulting in misdiagnosis.

SUMMERY OF THE UTILITY MODEL

Therefore, it is necessary to overcome the defects of the prior art and provide a pulse feeling device and a pulse feeling finger stall, which can be better combined with the pulse feeling of a doctor, thereby realizing the standardized pulse feeling, and the pulse feeling data can be used for back-end analysis and improving the accuracy of the pulse feeling data.

The technical scheme is as follows: a pulse feeling finger sleeve, comprising: the sleeve body is used for being sleeved at the end part of a finger; and the force sensor module is arranged on the sleeve body, the sleeve body is sleeved on the end part of the finger, and the force sensor module is in direct contact fit or indirect contact fit with the finger.

When the pulse feeling fingerstall is used, the end part of a finger is sleeved with the body, the pulse feeling, the guan pulse or the chi pulse on the wrist is contacted through the force sensor module, and the force sensor module can correspondingly acquire the pulse condition information of the pulse feeling, the guan pulse or the chi pulse and send the pulse condition information to the host equipment for analysis and storage processing. In addition, the end of the finger can synchronously sense pulse condition information of cun pulse, guan pulse or chi pulse when contacting the force sensor module. Therefore, the manual pulse taking and the force sensor module are integrated, so that the standardized pulse taking can be realized no matter a doctor uses or a common user uses, the pulse feeling data can be used for back-end analysis, and the accuracy of the pulse feeling data can be improved.

In one embodiment, the force sensor module is disposed at one end of the sleeve body, and after the sleeve body is sleeved on the end portion of the finger, the force sensor module is in direct contact fit or indirect contact fit with the end surface of the finger.

in one embodiment, the pulse feeling finger sleeve further comprises a cushion block, and the cushion block is replaceably arranged between the force sensor module and the sleeve body.

In one embodiment, an end face of the sleeve body is provided with an installation groove, and the cushion block is embedded into the installation groove.

In one embodiment, the sleeve body comprises a first sub sleeve and a second sub sleeve which are connected with each other; the first sub-sleeve is provided with a first concave part used for being attached to the side wall of the finger, the second sub-sleeve is provided with a second concave part used for being attached to the side wall of the finger, and the first concave part and the second concave part are spliced to form an insertion hole used for inserting the finger; the distance between the first branch sleeve and the second branch sleeve is adjustable.

In one embodiment, the first sub-sleeve is provided with a first connecting piece, the second sub-sleeve is provided with a second connecting piece, the first connecting piece is provided with a plurality of connecting positions, and the second connecting piece can be selectively and fixedly arranged at one of the connecting positions.

In one embodiment, the first connecting member is a connecting rod, the connecting position is a tooth socket arranged on a side wall of the connecting rod, a first movable hole is formed in a side wall of the second sub sleeve, the second connecting member is a limiting rod movably sleeved in the first movable hole, and the limiting rod is provided with a protrusion for limiting and matching with the tooth socket.

In one embodiment, the open side of the inner side wall of the second sleeve is provided with a step, and the open side of the first sleeve is movably arranged in the step.

in one embodiment, the pulse feeling finger sleeve further comprises two pressing plates, and the two pressing plates respectively and correspondingly press and fix two ends of the force sensor module on two opposite side walls of the sleeve body.

A pulse feeling device comprises the pulse feeling finger sleeve and a display, wherein the display is electrically connected with the force sensor module and is used for displaying pulse condition data information acquired by the force sensor module; the pulse feeling device further comprises a wearing element, the wearing element is connected with the display, and the wearing element is worn on the wrist.

The pulse feeling device comprises the pulse feeling finger sleeve, so that the technical effect is brought by the pulse feeling finger sleeve, the pulse feeling finger sleeve has the same beneficial effect as the pulse feeling finger sleeve, and the description is omitted. In addition, the display can collect pressure data on the pulse feeling finger sleeve and carry out data analysis, and the pressure data is fitted into a waveform to be displayed, so that medical personnel can directly observe pulse condition information conveniently; and related data can be wirelessly transmitted to a cloud server or a computer through a built-in wireless module of the system, so that big data can be acquired, and big data analysis is facilitated.

Drawings

fig. 1 is a schematic structural view of a pulse feeling finger stall according to an embodiment of the present invention;

fig. 2 is an exploded view of a pulse feeling finger cot according to an embodiment of the present invention;

Fig. 3 is an exploded schematic structural view of a first sleeve of a pulse feeling finger sleeve according to an embodiment of the present invention;

Fig. 4 is a schematic structural view illustrating a first connecting member and a second connecting member of a pulse feeling finger sleeve according to an embodiment of the present invention;

Fig. 5 is a schematic structural view of a pulse feeling device according to an embodiment of the present invention;

Fig. 6 is a schematic structural view of a pulse feeling device according to an embodiment of the present invention.

Reference numerals:

10. The pulse feeling finger stall comprises a pulse feeling finger stall body 11, a glove body 111, a mounting groove 112, a first sub-sleeve, a 1121, a first concave portion, 1122, a first connecting piece 1123, a tooth groove 113, a second sub-sleeve, 1131, a second concave portion 1132, a second connecting piece, 1133, a first movable hole, 1134, a protrusion, 1135, a second movable hole, 1136, an anti-falling plate, 1137, a spring, 1138, a step position, 12, a force sensor module, 13, a cushion block, 14, a pressing plate, 20, a display, 30 and a wearing element.

Detailed Description

in order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

in the description of the present invention, it is to be understood that the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the description of the present invention, it is to be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly connected" to another element, there are no intervening elements present.

In one embodiment, referring to fig. 1, a pulse feeling finger sleeve 10 includes: a sheath 11 and a force sensor module 12. The sleeve body 11 is used for sleeving the end part of the finger. The force sensor module 12 is arranged on the sleeve body 11, the sleeve body 11 is sleeved on the end part of the finger, and the force sensor module 12 is in direct contact fit or indirect contact fit with the finger.

when the pulse feeling finger sleeve 10 is used, the sleeve body 11 is sleeved on the end of a finger, and the force sensor module 12 is in contact with the cun pulse, guan pulse or chi pulse on the wrist, so that the force sensor module 12 can correspondingly acquire the pulse condition information of the cun pulse, guan pulse or chi pulse and send the pulse condition information to the host equipment for analysis and storage processing. In addition, the end of the finger can synchronously sense the pulse condition information of cun pulse, guan pulse or chi pulse when contacting the force sensor module 12. Therefore, the manual pulse taking and the pulse taking of the force sensor module 12 are integrated, no matter a doctor uses or a common user uses, the standardized pulse taking can be realized, the pulse feeling data can be used for back-end analysis, and the accuracy of the pulse feeling data can be improved.

Specifically, the force sensor module 12 is disposed at one end of the sheath body 11, the sheath body 11 is sleeved on the end portion of the finger, and the force sensor module 12 is in direct contact fit or indirect contact fit with the end surface of the finger. Optionally, the force sensor module 12 is disposed on a side wall of the sheath 11.

Further, referring to fig. 1 and 2, the pulse feeling finger sleeve 10 further includes a cushion block 13. The spacer 13 is arranged displaceably between the force sensor module 12 and the housing body 11. Therefore, as the replaceable cushion block 13 is arranged between the force sensor module 12 and the sleeve body 11, the material and the thickness of the cushion block 13 can be adjusted according to actual conditions, so as to promote the attachment of the end surface of the force sensor module 12 and the surface to be measured for taking pulse, and obtain more accurate pulse signals. In addition, in order to enable the cushion block 13 to be in contact with the end face of the finger well and enable the finger to better sense pulse condition information through the cushion block 13 and the force sensing module, the surface of the cushion block 13 in contact with the finger is matched with the end face of the finger, namely, the surface of the cushion block 13 in contact with the finger is provided with a concave surface. In addition, the surface of the cushion block 13 contacting with the force sensor module 12 is correspondingly a plane, which is beneficial to obtaining more accurate pulse signals.

in one embodiment, the end surface of the sheath body 11 is provided with a mounting groove 111, and the cushion block 13 is inserted into the mounting groove 111. So, cushion 13 is changed comparatively conveniently, and the installation is also comparatively stable simultaneously. Further, in order to facilitate the attachment of the end surface of the force sensor module 12 to the surface to be measured for taking pulse and obtain a more accurate pulse condition signal, optionally, the height of the cushion block 13 is equal to or greater than the height of the installation groove 111. In addition, the material of the cushion block 13 is the same as or different from that of the sleeve body 11.

In one embodiment, referring to fig. 1 and 2 again, the sheath body 11 includes a first sub-sheath 112 and a second sub-sheath 113 connected to each other. The first sub-sleeve 112 is provided with a first recess 1121 for fitting with the side wall of the finger, and the second sub-sleeve 113 is provided with a second recess 1131 for fitting with the side wall of the finger. The first recess 1121 and the second recess 1131 are combined to form an insertion hole for inserting a finger. The distance between the first sleeve 112 and the second sleeve 113 is adjustable. So, because the interval between first branch cover 112 and the second branch cover 113 is adjustable, the aperture size of the jack that first branch cover 112 and second branch cover 113 enclose to close the formation is according to the corresponding adjustment of size of finger for the jack can be adapted to the finger size betterly, adapts to the finger of the different thicknesses of different people, and the finger is difficult for droing after dressing.

Further, referring to fig. 2 to 4, the first sub-sleeve 112 is provided with a first connector 1122, and the second sub-sleeve 113 is provided with a second connector 1132. The first connecting member 1122 is provided with a plurality of connecting positions, and the second connecting member 1132 is selectively and fixedly arranged at one of the connecting positions. As such, when the second connector 1132 is fixed at different connection positions, the distance between the first sleeve 112 and the second sleeve 113 is different. The second connecting member 1132 is fixed at a proper connecting position, so that the insertion hole of the finger sleeve can be ensured to be suitable for the size of the finger, and the finger is not easy to fall off after being worn.

In one embodiment, the first connecting member 1122 is a connecting rod, and the connecting position is a tooth slot 1123 disposed on a side wall of the connecting rod. The lateral wall of the second sub-sleeve 113 is provided with a first movable hole 1133, the second connecting member 1132 is a limiting rod movably sleeved in the first movable hole 1133, and the limiting rod is provided with a protrusion 1134 for limiting and matching with the tooth slot 1123. So, during arch 1134 on the gag lever post inserted tooth's socket 1123, alright with spacing with the connecting rod, remove the gag lever post and make arch 1134 break away from out tooth's socket 1123, alright with the interval between adjustment first branch cover 112 and the second branch cover 113, simple structure, it is comparatively convenient to operate, first branch cover 112 is connected with the second branch cover 113 and is firm.

Specifically, referring to fig. 2 and 3, the sidewall of the second sleeve 113 is further provided with a second movable hole 1135 communicated with the first movable hole 1133. The connecting rod is movably sleeved in the second movable hole 1135. Therefore, the limiting rod and the connecting rod are sleeved in the movable hole and are not exposed in the insertion hole, and the limiting rod and the connecting rod can be prevented from being in contact with fingers, so that a good wearing effect is guaranteed.

in addition, in order to ensure a better fixing effect between the first sub-sleeve 112 and the second sub-sleeve 113, two first connecting members 1122 and two second connecting members 1132 are provided, and the two first connecting members 1122 and the two second connecting members 1132 are in one-to-one corresponding matching connection.

In addition, referring to fig. 2 and 4, the end of the limiting rod is provided with an anti-falling plate 1136 that is in limit fit with the outer side wall of the second sub-sleeve 113, and the anti-falling plate 1136 can prevent the limiting rod from falling off the first movable hole 1133. Further, the spring 1137 is sleeved on the limiting rod, one end of the spring 1137 is abutted to the anti-falling plate 1136, and the other end of the spring 1137 is abutted to the outer side wall of the second sub-sleeve 113. So, after pressing the gag lever post and making the arch 1134 on the gag lever post break away from tooth's socket 1123, spring 1137 is compressed to loosen the gag lever post after first branch cover 112 position adjustment, the gag lever post resets under the elasticity answer effect of spring 1137 and makes arch 1134 insert another tooth's socket 1123 again, and then plays limiting displacement, convenient operation to the connecting rod.

Optionally, the first sub-sleeve 112 and the second sub-sleeve 113 may also be detachably connected by an external connecting member, for example, the outer side wall of the first sub-sleeve 112 is provided with a clamping member, and the outer side wall of the second sub-sleeve 113 is provided with a plurality of clamping positions matched with the clamping member. When the clamping piece is matched and connected with one clamping position, the first sub-sleeve 112 and the second sub-sleeve 113 can be connected and fixed.

In one embodiment, referring to fig. 1 and fig. 2 again, the open side of the inner sidewall of the second sub-sleeve 113 is provided with a step 1138, and the open side of the first sub-sleeve 112 is movably disposed in the step 1138. Thus, the opening side of the first sub-sleeve 112 is sleeved on the step position 1138 on the opening side of the second sub-sleeve 113, the connection effect between the first sub-sleeve 112 and the second sub-sleeve 113 is stable, and in addition, when the first sub-sleeve 112 moves relative to the second sub-sleeve 113, the movement stability is good.

In one embodiment, referring to fig. 2 again, the pulse feeling finger sleeve 10 further includes two pressing plates 14. The two pressing plates 14 respectively press and fix two ends of the force sensor module 12 on two opposite side walls of the sleeve body 11. Specifically, the pressing plate 14 is detachably attached to the side wall of the housing 11 by a fastener. Such as screws, bolts or pins, etc. In addition, in order to facilitate the stable connection between the pressing plate 14 and the sleeve body 11, the outer side wall of the sleeve body 11 is square.

The force sensor module 12 includes a matrix pressure sensor, connecting wires (not shown), and a data processing chip (not shown). The matrix pressure sensor is provided with a plurality of pressure sensing surfaces contacted with the skin of a human body and is electrically connected with the data processing chip through a connecting lead. The matrix pressure sensors are superimposed on the surface of the pad 13.

Further, the pulse feeling finger sleeve 10 further comprises a sensor coating. The sensor coating is arranged on the side of the matrix pressure sensor, which faces away from the cushion block 13. The sensor coating plays a role in coating, fixing and protecting the matrix pressure sensor. In particular, the surface of the sensor cover membrane facing the matrix pressure sensor is provided with outwardly protruding particles. A plurality of the particles are arranged in a matrix, the position of each particle corresponds to the position of a pressure sensor unit in the matrix pressure sensor one by one, the influence of the adjacent sensor units when a single pressure sensor unit reads a numerical value is effectively avoided, and the sensor obtains a clearer and more accurate signal. The sensor coating film is arranged on the surface of the matrix pressure sensor, so that the effects of preventing pricking, preventing corrosion and the like are achieved, and the service life of the sensor is prolonged.

The pulse feeling finger cot 10 can be adapted to the following application scenes:

1. In the experimental scene, for example, three pulse feeling finger sleeves 10 worn by an experienced doctor are used for respectively feeling the cun pulse, the guan pulse and the chi pulse, the three pulse feeling finger sleeves 10 record pulse condition information in the pulse feeling process of the doctor and correspond to pulse feeling results of the doctor, namely, in the experimental scene, the digital pulse condition information data is labeled and stored, so that the stored pulse condition information can be used as a subsequent pulse feeling reference;

2. In a teaching scene, an inexperienced doctor or a student wears three pulse feeling finger sleeves 10 to respectively feel cun pulse, guan pulse and chi pulse, the three pulse feeling finger sleeves 10 synchronously acquire pulse condition information in the pulse feeling process of the inexperienced doctor or the student and are matched with the stored pulse condition information, the real pulse condition is analyzed through the rear end, and the inexperienced doctor or the student matches the analyzed real pulse condition with the own finger feeling, so that the learning effect can be achieved;

3. In a clinical diagnosis scene, for example, a doctor wears three pulse feeling finger sleeves 10 to respectively feel, close and chi pulses, the three pulse feeling finger sleeves 10 record pulse condition information synchronously in the pulse feeling process of the doctor, and the doctor can diagnose according to the pulse feeling information of the doctor and can also diagnose by referring to the pulse condition information sensed by the pulse feeling finger sleeves 10, so that the recording and auxiliary diagnosis effects can be achieved;

4. In a common family scene, a common user wears three pulse feeling finger sleeves 10 to respectively feel, close and measure the pulse, and the pulse feeling instrument can take the pulse and give a judgment.

In one embodiment, referring to fig. 5 and 6, a pulse feeling device includes the pulse feeling finger sleeve 10 according to any one of the above embodiments, and further includes a display 20. The display 20 is electrically connected to the force sensor module 12, and the display 20 is configured to display pulse condition data information obtained by the force sensor module 12.

The pulse feeling device comprises the pulse feeling finger sleeve 10, so that the technical effect is brought by the pulse feeling finger sleeve 10, and the pulse feeling finger sleeve 10 has the same beneficial effect and is not repeated. In addition, the display 20 can collect the pressure data on the pulse feeling finger sleeve 10 and perform data analysis, and the pressure data is fitted into a waveform to be displayed, so that the medical care personnel can directly observe the pulse condition information; and related data can be wirelessly transmitted to a cloud server or a computer through a built-in wireless module of the system, so that big data can be acquired, and big data analysis is facilitated.

Specifically, there are three pulse-feeling finger sleeves 10, and the three pulse-feeling finger sleeves 10 correspond to the cun pulse, guan pulse and chi pulse, respectively. The force sensor module 12 and display 20 may transmit pressure data in a wired or wireless manner. The display 20 collects the pressure data on the 3 pulse feeling finger sleeves 10, performs data analysis, fits into a waveform and displays the waveform; and related data can be wirelessly transmitted to a cloud server or a computer through a built-in wireless module of the system, so that big data can be acquired, and big data analysis is facilitated.

In one embodiment, the pulse feeling device further comprises a wearing element 30. The wearing element 30 is connected to the display 20, and the wearing element 30 is worn on the wrist. The wearing element 30 is embodied as a strap, a connecting string or a glove or the like connected to the display 20.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A pulse feeling finger stall is characterized by comprising:

The sleeve body is used for being sleeved at the end part of a finger; and

The force sensor module is arranged on the sleeve body, the sleeve body is sleeved on the end part of the finger, and the force sensor module is in direct contact fit or indirect contact fit with the finger.

2. The pulse feeling finger cot of claim 1, wherein the force sensor module is disposed at one end of the cot body, and after the cot body is fitted over the end of the finger, the force sensor module is in direct contact fit or indirect contact fit with the end surface of the finger.

3. The pulse feeling cuff of claim 2, further comprising a pad replaceably disposed between the force sensor module and the cuff body.

4. The pulse feeling finger cot of claim 3, wherein an installation groove is arranged on the end surface of the cot body, and the cushion block is embedded in the installation groove.

5. The pulse-taking finger cot of claim 1, wherein the cuff body comprises a first cuff and a second cuff connected to each other; the first sub-sleeve is provided with a first concave part used for being attached to the side wall of the finger, the second sub-sleeve is provided with a second concave part used for being attached to the side wall of the finger, and the first concave part and the second concave part are spliced to form an insertion hole used for inserting the finger; the distance between the first branch sleeve and the second branch sleeve is adjustable.

6. the pulse feeling finger cot of claim 5, wherein the first sub cot is provided with a first connecting member, the second sub cot is provided with a second connecting member, the first connecting member is provided with a plurality of connecting positions, and the second connecting member is selectively and fixedly arranged at one of the connecting positions.

7. The pulse feeling finger cot of claim 6, wherein the first connecting member is a connecting rod, the connecting position is a tooth socket disposed on a side wall of the connecting rod, a first movable hole is disposed on a side wall of the second sub-cot, the second connecting member is a limiting rod movably disposed in the first movable hole, and the limiting rod is provided with a protrusion for limiting and matching with the tooth socket.

8. The pulse feeling finger cot of claim 5, wherein the open side of the inner side wall of the second sub-cot is provided with a step position, and the open side of the first sub-cot is movably arranged in the step position.

9. the pulse feeling finger cot according to any one of claims 1 to 8, further comprising two pressing plates, wherein the two pressing plates respectively press and fix two ends of the force sensor module onto two opposite side walls of the cot body.

10. A pulse feeling device, comprising the pulse feeling finger sleeve of any one of claims 1 to 9, and further comprising a display, wherein the display is electrically connected with the force sensor module, and the display is used for displaying pulse condition data information acquired by the force sensor module; the pulse feeling device further comprises a wearing element, the wearing element is connected with the display, and the wearing element is worn on the wrist.