CN207924240U - Three mesh stereomicroscope relay systems - Google Patents

Abstract

The utility model discloses beam splitting plane mirror and the first speculum group are equipped in a kind of the first eyepiece image rotation channel of three mesh stereomicroscope relay system, the second speculum group is equipped in second eyepiece image rotation channel, third speculum group is equipped in third image rotation channel, beam splitting plane mirror is reached through the first speculum group and third speculum group at the first eye lens interface and at video interface respectively by the beam splitter to the first eyepiece image rotation channel injected at the first eye lens interface and in third image rotation channel；Second speculum group is by the light beam image rotation injected at the second eye lens interface at the second eye lens interface.The relay system whole process realizes image rotation by plane mirror, and occupied space is smaller and can effectively reduce cost.

Description

Three mesh stereomicroscope relay systems

Technical field

The utility model is related to microscope technology fields, more particularly to a kind of three mesh stereomicroscope image rotation systems System.

Background technology

The relay system of three mesh stereomicroscopes refers to that stereomicroscope usually provides two eyepiece channels to observe sample Outside, sample can easily be observed come industrial camera of plugging into, people by the image of display by also providing path channels all the way.It is existing Have the relay system of three mesh stereomicroscopes of technology usually using prism, such relay system occupied space is larger, cost compared with It is high.

Utility model content

The technical problems to be solved in the utility model is to provide a kind of three mesh stereomicroscope relay systems, the image rotation system System uses plane mirror, and compact-sized, occupied space is smaller, at low cost.

The technical solution of the utility model is to provide a kind of three mesh stereomicroscope image rotation systems having following structure System, including frame body, the frame body be equipped with the first eyepiece image rotation channel, the second eyepiece image rotation channel and with video interface the Three image rotation channels；The both ends in the first eyepiece image rotation channel are respectively equipped with the first object lens interface and the first eye lens interface, institute Beam splitting plane mirror and the first speculum group are equipped in the first eyepiece image rotation channel stated；The two of the second eyepiece image rotation channel End is respectively equipped with the second object lens interface and the second eye lens interface, and the second speculum is equipped in the second eyepiece image rotation channel Group；Third speculum group is equipped in the third image rotation channel；The beam splitting plane mirror turns for that will inject the first eyepiece As the light beam in channel is divided into the first light beam and the second light beam, first light beam is injected in the first eyepiece image rotation channel, institute The second light beam stated is injected in third image rotation channel；First speculum group is used for the first light beam image rotation to the first eyepiece Interface；Second speculum group is used to inject the light beam image rotation in the second eyepiece image rotation channel to the second eye lens interface Place；The third speculum group is used for the second light beam image rotation at the video interface.

After using the above structure, the three mesh stereomicroscope relay systems of the utility model have compared with prior art Following advantages：

Due to flat equipped with beam splitting in the first eyepiece image rotation channel of the three mesh stereomicroscope relay systems of the utility model Face mirror and the first speculum group, are equipped with the second speculum group in the second eyepiece image rotation channel, equipped with third in third image rotation channel Speculum group, beam splitting plane mirror will turn in the beam splitter to the first eyepiece image rotation channel injected at the first eye lens interface with third As in channel, being reached at the first eye lens interface and at video interface through the first speculum group and third speculum group respectively；Second Speculum group is by the light beam image rotation injected at the second eye lens interface at the second eye lens interface.The relay system whole process passes through plane Mirror realizes image rotation, and occupied space is smaller and can effectively reduce cost.

As an improvement, the beam splitting plane mirror is set to the top of the first object lens interface and the beam splitting plane mirror Upper end is tilted to the first eyepiece image rotation channel direction.The third speculum group includes the first plane mirror and the second plane Speculum, first plane mirror are located at the top of the beam splitting plane mirror, and first plane mirror is used It is reflected into second plane mirror in by the second light beam；The second plane mirror and first plane mirror It is oppositely arranged, the second plane mirror is used to second light beam being reflected at the video interface.Using It is compact-sized after such structure.

As an improvement, first speculum group includes third plane mirror, fourth plane speculum, the 5th plane Speculum and the 6th plane mirror；The third plane mirror is oppositely arranged with the beam splitting plane mirror, described Fourth plane speculum is oppositely arranged with the third plane mirror, the 5th plane mirror and the described the 4th Plane mirror is oppositely arranged, and the 6th plane mirror and the 5th plane mirror are oppositely arranged and the 5th Plane mirror is equipped with the lower section of first eye lens interface；The third plane mirror is used for first light Beam is reflected on the fourth plane speculum, and the fourth plane speculum is for first light beam to be reflected into On 5th plane mirror, the 5th plane mirror is used to the first light beam being reflected into the 6th plane mirror, institute The 6th plane mirror stated is used to the first light beam being reflected at first eye lens interface.The third plane reflection Mirror, fourth plane mirror and the 5th plane mirror are located at the first eyepiece image rotation channel far from the beam splitting plane mirror In side.It is compact-sized after adopting the structure.

As an improvement, second speculum group includes the 7th plane mirror, the 8th plane mirror, the 9th plane Speculum, the tenth plane mirror and the 11st plane mirror；7th plane mirror is located at second object The top of mirror interface, the 8th plane mirror are oppositely arranged with the 7th plane mirror, and the described the 9th is flat Face speculum is oppositely arranged with the 8th plane mirror, and the tenth plane mirror and the 9th plane are anti- It penetrates mirror to be oppositely arranged, the 11st plane mirror is oppositely arranged with the tenth plane mirror and the 11st is flat Face speculum is located at the lower section of second eye lens interface；7th plane mirror turns for that will inject the second eyepiece As the light beam in channel is reflected on the 8th plane mirror, the 8th plane mirror is used to reflect the light beam Onto the 9th plane mirror, the 9th plane mirror is used to the light beam being reflected into the tenth plane mirror On, the tenth plane mirror is used to the light beam being reflected into the 11st plane mirror, and the described the 11st Plane mirror is used to the light beam being reflected at second eye lens interface.8th plane mirror, Nine plane mirrors and the tenth plane mirror are located at the second eyepiece image rotation channel far from the 7th plane reflection In the side of mirror.It is compact-sized after adopting the structure.

Description of the drawings

Fig. 1 is the dimensional structure diagram of the three mesh stereomicroscope relay systems of the utility model.

Fig. 2 is the main structure diagram of the three mesh stereomicroscope relay systems of the utility model.

Fig. 3 is the schematic cross-sectional view in the directions A-A in Fig. 2.

Fig. 4 is the overlooking structure diagram of the three mesh stereomicroscope relay systems of the utility model.

Fig. 5 is the schematic cross-sectional view in the directions B-B in Fig. 4.

Fig. 6 is the part index path of the three mesh stereomicroscope relay systems of the utility model.

As shown in the figure：1, frame body, the 2, first eyepiece image rotation channel, the 3, second eyepiece image rotation channel, 4, connecting bracket, 5, Three image rotation channels, 6, video interface, the 7, first object lens interface, the 8, first eye lens interface, 9, beam splitting plane mirror, the 10, second object lens Interface, the 11, second eye lens interface, the 12, first plane mirror, 13, second plane mirror, 14, third plane mirror, 15, fourth plane speculum, the 16, the 5th plane mirror, the 17, the 6th plane mirror, the 18, the 7th plane mirror, 19, Eight plane mirrors, the 20, the 9th plane mirror, the 21, the tenth plane mirror, the 22, the 11st plane mirror.

Specific implementation mode

It is specific embodiment of the utility model and in conjunction with attached drawing below, the technical solution of the utility model is made further Description, but the utility model is not limited to these examples.

As shown in Figures 1 to 6, the three mesh stereomicroscope relay systems of the utility model include frame body 1, the frame body 1 both sides are respectively equipped with channel, which is respectively the first eyepiece image rotation channel 2 and the second eyepiece image rotation channel 3.It is described The upside of frame body 1 be equipped with connecting bracket 4, the connecting bracket 4 is equipped with the third image rotation channel 5 with video interface 6.It is described The both ends in the first eyepiece image rotation channel 2 be respectively equipped with the first object lens interface 7 and the first eye lens interface 8.First eyepiece Beam splitting plane mirror 9 and the first speculum group are equipped in image rotation channel 2.The both ends in the second eyepiece image rotation channel 3 are set respectively There are the second object lens interface 10 and the second eye lens interface 11, the second speculum group is equipped in the second eyepiece image rotation channel 3.Institute Third speculum group is equipped in the third image rotation channel 5 stated.

The beam splitting plane mirror 9 is used to the light beam injected in the first eyepiece image rotation channel 2 being divided into the first light beam and the Two light beams, first light beam are injected in the first eyepiece image rotation channel 2, and second light beam injects third image rotation channel 5 It is interior.First speculum group is used for the first light beam image rotation at the first eye lens interface 8.Second speculum group is used In the light beam image rotation in the second eyepiece image rotation channel 3 will be injected at the second eye lens interface 11.The third speculum group is used In by the second light beam image rotation at the video interface 6.

The beam splitting plane mirror 9 be set to the first object lens interface 7 top and the beam splitting plane mirror 9 upper end to First eyepiece image rotation channel, 2 direction tilts.

The third speculum group includes the first plane mirror 12 and second plane mirror 13, and described first is flat Face speculum 12 is located at the top of the beam splitting plane mirror 9, and first plane mirror 12 is used for the second light beam is anti- It is mapped in second plane mirror 13, the incident angle of first plane mirror 12 is 45 °；Second plane is anti- It penetrates mirror 13 to be oppositely arranged with first plane mirror 12, the second plane mirror 13 is used for described second Light beam is reflected at the video interface 6, and the incident angle of the second plane mirror 13 is 45 °.

First speculum group includes third plane mirror 14, fourth plane speculum 15, the 5th plane reflection Mirror 16 and the 6th plane mirror 17；The third plane mirror 14 is oppositely arranged with the beam splitting plane mirror 9, described Fourth plane speculum 15 be oppositely arranged with the third plane mirror 14, the 5th plane mirror 16 and institute The fourth plane speculum 15 stated is oppositely arranged, the 6th plane mirror 17 and 16 phase of the 5th plane mirror To the lower section of setting and the 5th plane mirror 16 equipped with first eye lens interface 8；The third plane mirror 14 for first light beam to be reflected into the fourth plane speculum 15, and the fourth plane speculum 15 is used It is reflected on the 5th plane mirror 16 in by first light beam, the 5th plane mirror 16 is used for the first light Beam is reflected on the 6th plane mirror 17, and the 6th plane mirror 17 is used to the first light beam being reflected into described the At one eye lens interface 8.Third plane mirror 14, fourth plane mirror 15 and the 5th plane mirror 16 is located at described In first side of the eyepiece image rotation channel 2 far from the beam splitting plane mirror 9.The third plane mirror 14, Siping City The incident angle of face speculum 15, the 5th plane mirror 16 and the 6th plane mirror 17 is 45 °.

Second speculum group includes the 7th plane mirror 18, the 8th plane mirror 19, the 9th plane reflection Mirror 20, the tenth plane mirror 21 and the 11st plane mirror 22；7th plane mirror 18 is located at described the The top of two object lens interfaces 10, the 8th plane mirror 19 are oppositely arranged with the 7th plane mirror 18, institute The 9th plane mirror 20 stated is oppositely arranged with the 8th plane mirror 19, described tenth plane mirror 21 with 9th plane mirror 20 is oppositely arranged, the 11st plane mirror 22 and the tenth plane mirror 21 are oppositely arranged and the 11st plane mirror 22 is located at the lower section of second eye lens interface 8；7th plane Speculum 18 is used to the light beam injected in the second eyepiece image rotation channel 3 being reflected into the 8th plane mirror 19, and described the Eight plane mirrors 19 are used to the light beam being reflected into the 9th plane mirror 20, the 9th plane mirror 20 For the light beam to be reflected into the tenth plane mirror 21, the tenth plane mirror 21 is used for the light Beam is reflected on the 11st plane mirror 22, and the 11st plane mirror 22 is used to the light beam being reflected into institute At the second eye lens interface 11 stated.8th plane mirror 19, the 9th plane mirror 20 and the tenth plane mirror 21 are located in second side of the eyepiece image rotation channel 3 far from the 7th plane mirror 18.Described the 7th is flat Face speculum 18, the 8th plane mirror 19, the 9th plane mirror 20, the tenth plane mirror 21 and the 11st plane reflection The incident angle of mirror 22 is 45 °.

The course of work of the three mesh stereomicroscope relay systems of the utility model is as follows：

Light beam is injected at the first object lens interface 7, and the first light beam and the second light beam are divided into after beam splitting plane mirror 9；Described First light beam is mapped on third plane mirror 14 back reflection to fourth plane speculum 15, then through fourth plane speculum 15 It is reflected on the 5th plane mirror 16, is then reflected into the 6th plane mirror 17 through the 5th plane mirror 16, subsequently It is reflected at the first eye lens interface 8 through the 6th plane mirror 17, the imaging of object can be showed on the first eyepiece in this way.

Meanwhile second light beam is mapped on the first plane mirror 12 back reflection to second plane mirror 13, so It is reflected at video interface by second plane mirror 13, the imaging of object can be showed in this way on video equipment.

Meanwhile light beam injects at the second object lens interface 10 that be irradiated to 18 back reflection of the 7th plane mirror anti-to the 8th plane It penetrates on mirror 19, is then reflected on the 9th plane mirror 20 through the 8th plane mirror 19, then through the 9th plane mirror 20 are reflected on the tenth plane mirror 21, are then reflected on the 11st plane mirror 22 through the tenth plane mirror 21,

As soon as being subsequently reflected at the second eye lens interface 11 through the tenth plane mirror 22, the energy in this way on the second eyepiece Show the imaging of object.

Above description is only the better embodiment of the application and the explanation to institute's application technology principle.Art technology Personnel should be appreciated that utility model range involved in the application, however it is not limited to which the specific of above-mentioned technical characteristic is closed certainly Technical solution, while should also cover in the case where not departing from utility model design, by above-mentioned technical characteristic or its etc. The other technologies scheme for carrying out arbitrary combination with feature and being formed.Such as features described above with it is disclosed herein（But it is not limited to） Technical characteristic with similar functions is replaced mutually and the technical solution that is formed.

Claims (7)

1. a kind of three mesh stereomicroscope relay systems, it is characterised in that：Including frame body, the frame body is equipped with the first eyepiece Image rotation channel, the second eyepiece image rotation channel and the third image rotation channel with video interface；The first eyepiece image rotation channel Both ends are respectively equipped with the first object lens interface and the first eye lens interface, and beam splitting plane mirror is equipped in the first eyepiece image rotation channel With the first speculum group；The both ends in the second eyepiece image rotation channel are respectively equipped with the second object lens interface and the second eyepiece connects Mouthful, the second speculum group is equipped in the second eyepiece image rotation channel；Third is equipped in the third image rotation channel to reflect Microscope group；

The beam splitting plane mirror is used to the light beam injected in the first eyepiece image rotation channel being divided into the first light beam and the second light beam, First light beam is injected in the first eyepiece image rotation channel, and second light beam is injected in third image rotation channel；

First speculum group is used for the first light beam image rotation at the first eye lens interface；

Second speculum group is used to inject the light beam image rotation in the second eyepiece image rotation channel at the second eye lens interface；

The third speculum group is used for the second light beam image rotation at the video interface.

2. three mesh stereomicroscope relay system according to claim 1, it is characterised in that：The beam splitting plane mirror is set It is tilted to the first eyepiece image rotation channel direction in the top of the first object lens interface and the upper end of the beam splitting plane mirror.

3. three mesh stereomicroscope relay system according to claim 2, it is characterised in that：The third speculum group Including the first plane mirror and second plane mirror, first plane mirror is located at the beam splitting plane mirror Top, first plane mirror are used to the second light beam being reflected into second plane mirror；Second plane Speculum is oppositely arranged with first plane mirror, and the second plane mirror is used for second light beam It is reflected at the video interface.

4. three mesh stereomicroscope relay system according to claim 1, it is characterised in that：First speculum group Including third plane mirror, fourth plane speculum, the 5th plane mirror and the 6th plane mirror；The third is flat Face speculum is oppositely arranged with the beam splitting plane mirror, the fourth plane speculum and the third plane mirror It is oppositely arranged, the 5th plane mirror is oppositely arranged with the fourth plane speculum, and the 6th plane is anti- It penetrates mirror and the 5th plane mirror is oppositely arranged and the 5th plane mirror is equipped with first eye lens interface Lower section；The third plane mirror is used to for first light beam to be reflected into the fourth plane speculum, institute The fourth plane speculum stated is used to first light beam being reflected into the 5th plane mirror, and the 5th plane is anti- Mirror is penetrated for the first light beam to be reflected into the 6th plane mirror, the 6th plane mirror is used for the first light beam is anti- It is mapped at first eye lens interface.

5. three mesh stereomicroscope relay system according to claim 4, it is characterised in that：The third plane reflection Mirror, fourth plane mirror and the 5th plane mirror are located at the first eyepiece image rotation channel far from the beam splitting plane mirror In side.

6. three mesh stereomicroscope relay system according to claim 1, it is characterised in that：Second speculum group It is anti-including the 7th plane mirror, the 8th plane mirror, the 9th plane mirror, the tenth plane mirror and the 11st plane Penetrate mirror；7th plane mirror is located at the top of the second object lens interface, the 8th plane mirror with 7th plane mirror is oppositely arranged, and the 9th plane mirror is opposite with the 8th plane mirror to be set It sets, the tenth plane mirror is oppositely arranged with the 9th plane mirror, the 11st plane mirror It is oppositely arranged with the tenth plane mirror and the 11st plane mirror is located under second eye lens interface Side；7th plane mirror is used to the light beam injected in the second eyepiece image rotation channel being reflected into the 8th plane mirror On, the 8th plane mirror is used to the light beam being reflected into the 9th plane mirror, the 9th plane Speculum is used to the light beam being reflected into the tenth plane mirror, and the tenth plane mirror is used for will be described Light beam is reflected on the 11st plane mirror, and the 11st plane mirror is used to the light beam being reflected into described The second eye lens interface at.

7. three mesh stereomicroscope relay system according to claim 6, it is characterised in that：8th plane reflection Mirror, the 9th plane mirror and the tenth plane mirror are located at the second eyepiece image rotation channel far from the 7th plane In the side of speculum.