CN211985393U

CN211985393U - Improved generation eyeball protrusion degree dipperstick

Info

Publication number: CN211985393U
Application number: CN201922477519.XU
Authority: CN
Inventors: 姜艳华
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-11-24
Anticipated expiration: 2029-12-31

Abstract

The utility model relates to an improved eyeball protrusion measuring scale, which comprises scales; the measuring structure comprises a measuring structure A, an ultraviolet irradiation lamp structure, an adjusting structure, a spring structure, a measuring structure B and an ultraviolet receiver, wherein the scale is arranged on the side wall of the measuring structure, the measuring structure comprises a rotating shaft, a cylinder A, a groove A and a fixed column, the scale is arranged on the side wall of the cylinder A, the groove A is arranged on the side wall of the cylinder A, the fixed column is fixed at the bottom end inside the cylinder A, and the rotating shaft is installed inside the cylinder A; the measuring structure B is fixed at one end of the adjusting structure; the ultraviolet receiver is arranged on the side wall of the column body B. The utility model provides an improved generation eyeball protrusion degree dipperstick is when measuring the outstanding height of eyeball for patient, avoids direct contact eyeball, causes the injury to the human eye.

Description

Improved generation eyeball protrusion degree dipperstick

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to an improved generation eyeball protrusion degree dipperstick.

Background

At present, in the medical field, the invention of the eyeball protrusion measuring ruler is beneficial to checking the protrusion of human eyes so as to carry out corresponding treatment according to the condition of the eyes.

Some eyeball protrusion dipperstick of current causes the injury to the people's eye easily when measuring.

Therefore, there is a need to provide an improved eyeball protrusion measuring ruler to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem avoid direct contact eyeball, cause injury an improved generation eyeball protrusion dipperstick to the human eye.

In order to solve the technical problem, the utility model provides a pair of improved generation eyeball protrusion degree dipperstick includes: calibration; the measuring structure comprises a measuring structure A, an ultraviolet irradiation lamp structure, an adjusting structure, a spring structure, a measuring structure B and an ultraviolet receiver, wherein the scale is arranged on the side wall of the measuring structure, the measuring structure comprises a rotating shaft, a cylinder A, a groove A and a fixed column, the scale is arranged on the side wall of the cylinder A, the groove A is arranged on the side wall of the cylinder A, the fixed column is fixed at the bottom end inside the cylinder A, and the rotating shaft is installed inside the cylinder A; the ultraviolet irradiation lamp structure is arranged at the bottom end of the rotating shaft and comprises an ultraviolet irradiation lamp and a connecting ring, the connecting ring is arranged at the bottom end of the rotating shaft, and the ultraviolet irradiation lamp is fixed at one end of the connecting ring; the adjusting structure is fixed on the side wall of the column body A; the spring structure is fixed on the side wall of the adjusting structure and comprises a spring and a baffle plate, the baffle plate is fixed on the side wall of the adjusting structure, and the spring is fixed at one end of the baffle plate; the measuring structure B is fixed at one end of the adjusting structure and comprises a cylinder B and a groove C, the cylinder B is fixed at one end of the adjusting structure, and the groove B is arranged on the side wall of the cylinder B; the ultraviolet receiver is arranged on the side wall of the column body B.

Preferably, the scale precision is 0.1mm, and the scale is evenly located the recess A with the border of recess B.

Preferably, the rotating shaft is rotatably connected to the connecting ring, and the rotating shaft is in threaded connection with the fixing column.

Preferably, the column body a and the column body B are parallel to each other, the groove a and the groove B are in a relative rotation state, and the ultraviolet irradiation lamp and the ultraviolet receiver are parallel to each other and are in a relative state.

Preferably, the adjusting structure comprises a stud, a nut, threads, a fixing rod and a groove C, the fixing rod is fixed on the side walls of the cylinder A and the cylinder B respectively, the stud is installed at one end of the fixing rod, the threads are arranged on the side walls of the stud, the nut is installed on the side walls of the stud, and the groove C is arranged on the side walls of the stud.

Preferably, one end of each fixing rod is rotatably connected with the corresponding stud, the spring penetrates through the stud, and the spring is fixed between the two fixing rods.

Preferably, the width of the fixing rod is smaller than that of the groove C, and the nut is in threaded connection with the stud.

Compared with the prior art, the utility model discloses positioner of improved generation eyeball protrusion degree dipperstick has following beneficial effect:

the utility model provides an improved generation eyeball protrusion degree dipperstick, when measuring eyeball protrusion degree for patient, will measurement structure A with measurement structure B puts at the both ends of patient's canthus perpendicularly, then rotates adjustment structure makes spring structure compression or expansion makes measurement structure A with the length symmetry between measurement structure B and patient's the orbit makes and installs inside measurement structure B ultraviolet receiver's bottom is parallel with the eye cornea symmetry, then rotates and adjusts measurement structure A, makes measurement structure A's bottom also be parallel with patient's eye cornea symmetry, then lets patient look forward, then opens ultraviolet radiation lamp structure, makes ultraviolet radiation lamp structure launch the ultraviolet ray, and the ultraviolet ray shines on ultraviolet receiver, observes ultraviolet receiver surface does not show the height of receiving the ultraviolet ray, the height of the eyeball of the patient is the protrusion height, and in the process, the direct contact with the eyeball of the patient is avoided, so that the injury to the patient is avoided.

Drawings

Fig. 1 is a schematic structural view of a preferred embodiment of the improved eyeball protrusion measuring scale provided by the present invention;

FIG. 2 is a schematic view of the structure of measurement A and measurement B shown in FIG. 1;

FIG. 3 is a schematic view of the internal structure of measurement A shown in FIG. 1;

fig. 4 is a schematic view of the adjustment structure shown in fig. 1.

Reference numbers in the figures: 1. adjusting structure, 11, the double-screw bolt, 12, the nut, 13, the screw thread, 14, the dead lever, 15, recess C, 2, spring structure, 21, the spring, 22, the baffle, 3, measurement structure A, 31, the pivot, 32, cylinder A, 33, recess A, 34, fixed column, 4, measurement structure B, 41, cylinder B, 42, recess B, 5, the scale, 6, ultraviolet ray lamp structure, 61, ultraviolet ray lamp, 62, the clamping ring, 7, ultraviolet ray receiver.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural view of a preferred embodiment of an improved measuring ruler for eyeball protrusion degree according to the present invention; FIG. 2 is a schematic view of the structure of measurement A and measurement B shown in FIG. 1; fig. 3 is a schematic view of the internal structure of the measurement a shown in fig. 1, and fig. 4 is a schematic view of the adjustment structure shown in fig. 1, wherein the improved measuring ruler for measuring the protrusion degree of eyeball comprises: scale 5; the measuring structure A3, the ultraviolet irradiation lamp structure 6, the adjusting structure 1, the spring structure 2, the measuring structure B4 and the ultraviolet receiver 7, the scale 5 is arranged on the side wall of the measuring structure A3, the measuring structure A comprises a rotating shaft 31, a cylinder A32, a groove A33 and a fixed column 34, the scale 5 is arranged on the side wall of the cylinder A32, the groove A33 is arranged on the side wall of the cylinder A32, the fixed column 34 is fixed at the bottom end of the inside of the cylinder A32, and the rotating shaft 31 is installed inside the cylinder A32; the ultraviolet radiation lamp structure 6 is mounted at the bottom end of the rotating shaft 31, the ultraviolet radiation lamp structure 6 comprises an ultraviolet radiation lamp 61 and a connecting ring 62, the connecting ring 62 is mounted at the bottom end of the rotating shaft 31, and the ultraviolet radiation lamp 61 is fixed at one end of the connecting ring 62; the adjusting structure 1 is fixed on the side wall of the column A32; the spring structure 2 is fixed on the side wall of the adjusting structure 1, the spring structure 2 comprises a spring 21 and a baffle 22, the baffle 22 is fixed on the side wall of the adjusting structure 1, and the spring 21 is fixed at one end of the baffle 22; the measuring structure B4 is fixed at one end of the adjusting structure 1, the measuring structure B4 comprises a column B41 and a groove C42, the column B41 is fixed at one end of the adjusting structure 1, and the groove B42 is arranged on the side wall of the column B41; the ultraviolet receiver 7 is mounted on the side wall of the column B41.

In the specific implementation process, as shown in fig. 2, the accuracy of the scale 5 is 0.1mm, and the scale 5 is uniformly arranged at the edges of the groove a33 and the groove B42, so that the scale 5 can be directly observed by the naked eye of a person, and the scales 5 arranged at the edges of the groove a33 and the groove B42 are on the same horizontal line.

In a specific implementation process, as shown in fig. 1, the rotating shaft 31 is rotatably connected to the connecting ring 62, and the rotating shaft 31 is threadedly connected to the fixing post 34, so that the position of the ultraviolet radiation lamp 61 can be adjusted by rotating the rotating shaft 31.

In the specific implementation process, as shown in fig. 1, the column a32 is parallel to the column B41, the groove a33 is opposite to the groove B42, and the ultraviolet radiation lamp 61 is parallel to and opposite to the ultraviolet receiver 7, so that all the light emitted by the ultraviolet radiation lamp 61 can be received by the ultraviolet receiver 7.

In a specific implementation process, as shown in fig. 1, the adjusting structure 1 includes a stud 11, a nut 12, a thread 13, a fixing rod 14 and a groove C15, the fixing rod 14 is respectively fixed to the side walls of the column a32 and the column B41, the stud 11 is mounted at one end of the fixing rod 14, the thread 13 is disposed on the side wall of the stud 11, the nut 12 is mounted on the side wall of the stud 11, and the groove C15 is disposed on the side wall of the stud 11, so that the distance between the column a32 and the column B41 can be adjusted according to the degree of the eye socket.

In a specific implementation process, as shown in fig. 1, one end of the fixing rod 14 is rotatably connected to the stud 11, the spring 21 penetrates through the stud 11, the spring 21 is fixed between the two fixing rods 14, and an angle between the fixing rod 14 and the stud 11 can be adjusted.

In a specific implementation, as shown in fig. 1, the width of the fixing rod 14 is smaller than the width of the groove C15, and the nut 12 is screwed with the stud 11, so that the fixing rod 14 can be compressed into the groove C15 when the nut 12 is turned.

The utility model provides an improved generation eyeball protrusion dipperstick's theory of operation as follows: when a patient needs to measure the protrusion of the eyeball, the column A32 and the column B41 are vertically placed on two sides of the orbit of the patient, then the nut 12 is rotated towards the bottom end of the stud 11, the bottom end of the nut 12 compresses the fixing rod 14, the fixing rod 14 is rotated inwards to drive the spring 21 to be compressed inwards, the fixing rod 14 is rotated inwards to drive the column A32 and the column B41 to move towards the middle, the distance between the column A32 and the column B41 is equal to the length of the orbit, then the bottom end of the ultraviolet receiver 7 is parallel to the position of the cornea of the eye of the patient, the rotating shaft 31 is rotated to adjust the position of the ultraviolet irradiation lamp 61, the bottom end of the ultraviolet irradiation lamp 61 is parallel to the cornea of the eye of the patient, and the ultraviolet irradiation lamp 61 and the bottom end of the ultraviolet receiver 7 are on a horizontal line, then, the patient looks straight ahead to enable the eyeball to reach the maximum protrusion degree, then the ultraviolet radiation lamp 61 is started to enable the light emitted by the ultraviolet radiation lamp 61 to irradiate the surface of the ultraviolet receiver 7, then the height of the ultraviolet light irradiating the surface of the ultraviolet receiver 7 is observed, according to the scales 5 arranged around the ultraviolet receiver 7, the scales which are not irradiated are the height of the eyeball protrusion degree of the patient, and after the eyeball protrusion degree of the patient is read, the ultraviolet radiation lamp 61 is closed, so that the direct contact between an instrument and the eyeball of the patient is avoided in the process, and the corresponding injury to the eyeball of the patient is avoided.

Compared with the prior art, the utility model provides an improved generation eyeball protrusion degree dipperstick has following beneficial effect: the utility model provides an improved generation eyeball protrusion degree dipperstick, when measuring eyeball protrusion degree for patient, will measurement structure A3 with measurement structure B4 puts at the both ends of patient's canthus perpendicularly, then rotates regulation structure 1 makes spring structure 2 compress or expand, makes measurement structure A3 with the length symmetry between measurement structure B4 and patient's orbit makes install in measurement structure B4 inside the bottom of ultraviolet receiver 7 is parallel with the symmetry of cornea, then rotates regulation measurement structure A3, makes the bottom of measurement structure A3 also be parallel with patient's symmetry of cornea, then lets patient look ahead, then opens ultraviolet irradiation lamp structure 6, makes ultraviolet ray irradiation structure 6 launch the ultraviolet ray, the ultraviolet ray irradiates on ultraviolet receiver 7, observe ultraviolet receiver 7 surface does not demonstrate the height that receives the ultraviolet ray, the height of the eyeball of the patient is the protrusion height, and in the process, the direct contact with the eyeball of the patient is avoided, so that the injury to the patient is avoided.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent processes of the present invention are used in the specification and the attached drawings, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims

1. An improved eyeball protrusion measuring scale, which is characterized by comprising:

scale (5)

The measuring structure A (3), the scale (5) is arranged on the side wall of the measuring structure A (3), the measuring structure A (3) comprises a rotating shaft (31), a cylinder A (32), a groove A (33) and a fixing column (34), the scale (5) is arranged on the side wall of the cylinder A (32), the groove A (33) is arranged on the side wall of the cylinder A (32), the fixing column (34) is fixed at the bottom end of the inside of the cylinder A (32), and the rotating shaft (31) is installed inside the cylinder A (32);

an ultraviolet radiation lamp structure (6), wherein the ultraviolet radiation lamp structure (6) is installed at the bottom end of the rotating shaft (31), the ultraviolet radiation lamp structure (6) comprises an ultraviolet radiation lamp (61) and a connecting ring (62), the connecting ring (62) is installed at the bottom end of the rotating shaft (31), and the ultraviolet radiation lamp (61) is fixed at one end of the connecting ring (62);

the adjusting structure (1), the adjusting structure (1) is fixed on the side wall of the column body A (32);

the spring structure (2) is fixed on the side wall of the adjusting structure (1), the spring structure (2) comprises a spring (21) and a baffle plate (22), the baffle plate (22) is fixed on the side wall of the adjusting structure (1), and the spring (21) is fixed at one end of the baffle plate (22);

the measuring structure B (4), the measuring structure B (4) is fixed at one end of the adjusting structure (1), the measuring structure B (4) comprises a column body B (41) and a groove B (42), the column body B (41) is fixed at one end of the adjusting structure (1), and the groove B (42) is arranged on the side wall of the column body B (41);

and the ultraviolet receiver (7), wherein the ultraviolet receiver (7) is arranged on the side wall of the column body B (41).

2. The improved ruler of claim 1, wherein said scale (5) has a precision of 0.1mm, and said scale (5) is uniformly disposed on the edges of said groove A (33) and said groove B (42).

3. The improved ruler of claim 1, wherein said shaft (31) is rotatably connected to said ring (62) and said shaft (31) is threadedly connected to said fixing post (34).

4. The improved ruler of claim 1, wherein the column A (32) and the column B (41) are parallel, the groove A (33) and the groove B (42) are in a relative rotation state, and the ultraviolet radiation lamp (61) and the ultraviolet receiver (7) are parallel and in a relative state.

5. The improved eyeball protrusion measuring scale as claimed in claim 1, wherein the adjusting structure (1) comprises a stud (11), a nut (12), a thread (13), a fixing rod (14) and a groove (15), the fixing rod (14) is fixed on the side walls of the column body A (32) and the column body B (41) respectively, the stud (11) is installed at one end of the fixing rod (14), the thread (13) is installed on the side wall of the stud (11), the nut (12) is installed on the side wall of the stud (11), and the groove (15) is installed on the side wall of the stud (11).

6. The improved ruler of claim 5, wherein one end of said fixing rod (14) is rotatably connected to said stud (11), said spring (21) penetrates inside said stud (11), and said spring (21) is fixed between two fixing rods (14).

7. The improved emittance gauge according to claim 5, wherein the width of said fixing rod (14) is smaller than the width of said groove C (15), and said nut (12) is threadedly coupled with said stud (11).