RU48228U1 - PHOTO TUBE FOR MICROSCOPE - Google Patents

Abstract

The design relates to microscopic technology and allows you to connect the camera for digital shooting with a microscope. A phototube is a monolithic cylindrical hollow tube, consisting of two sections of different diameters and symmetrical with respect to the central axis; from the end end, a section of a larger diameter from the outside has an annular ledge for a digital camera. The phototube is mounted on one of the eyepieces of the microscope or on the photo-video output of the trinocular nozzle. When installing the phototube on the photo-video output of the trinocular nozzle, it is equipped with a sleeve. The design is simple to manufacture, convenient to operate, easy to install and remove, provides the ability to conduct high-quality shooting of micro-objects in scientific research and to obtain high-quality images at low cost. 1 p., 2 cpf, 2 Fig.

Description

The invention relates to nozzle designs for connecting digital cameras with microscopes to obtain images of microobjects.

The introduction of computer technology in research using microscopic technology provides great opportunities for the study of micro-objects. The microimage can not only be observed directly on the computer monitor, but also adjusted to obtain greater clarity, save and receive prints.

The cost of modern microscopes equipped with digital photographic equipment is quite high and inaccessible to budgetary research organizations.

To help researchers, various adapters have been developed and are offered by firms that allow you to connect digital devices for photographing images of objects with microscopes. The adapter can be installed directly on the eyepiece of the microscope using special devices or connect a digital video device to the microscope through a special photo-video output of this microscope.

Known models of photo adapters for installing digital cameras on research microscopes through microphoton. Famous photo adapters are designed to install digital devices NIKON COOLPIX 990 (950) or OLYMPUS CAMEDIA S-3040 through microfusion unit MFN-11 or MFN-12 [http://www.zenit-npk.ru] [1].

These photo adapters are not cheap (350-400 cu) and are not universal, as other types of digital devices require their special

manufacture. Therefore, the need for their application is associated with significant costs of time and money. In addition, the MFN-11 and MFN-12 microphotographic nozzles, developed in the middle of the last century for the simultaneous observation and photographing of objects on camera film, have a built-in additional magnification device. Known devices for color rendering and resolution do not meet modern requirements. Image quality is poor.

A known system of photo and video capture for microscopes Mikmed 1 and Mikmed 2 based on an analog camera Sony [http://www.medmicro.ru] [2]. On your computer, you can record video in Mred4 format or take high-quality pictures. The system is inaccessible due to the high cost.

Known universal digital USB video eyepiece, installed instead of a conventional eyepiece or in the socket of the trinocular nozzle using a cylindrical connecting cartridge [http://www.medmicro.ru] [2].

The disadvantages of the video eyepiece include the low maximum resolution of 640 * 480 pixels, the presence of the accompanying video and photo capture programs, and the long-term digitization of the resulting image.

A universal adapter is known for attaching a camera to a telescope, microscope or other similar optical device [Patent 5 053794 US, IPC G 03 B 029/00. Universal adapter for attaching a camera to associated optical devices such as telescopes, microscopes and the like / Benz William G., Pub. 01.10.1991] [H].

The disadvantage of the universal adapter is the impossibility of installing it on the photo-video output of the trinocular nozzle of the microscope, which does not allow you to free the eyepieces and makes it impossible to simultaneously observe the object and record it.

A common disadvantage of the known solutions is the high cost and the associated high material costs.

Known devices are technically complex structures and therefore their operation is quite expensive.

The technical result of the utility model is to increase the quality and level of information in the study of microobjects using microscopes, reducing material costs when photographing microobjects.

The technical result is ensured by the construction of a phototube for mounting a digital camera on one of the eyepieces of the microscope or on the photo-video output of the trinocular nozzle, which is a monolithic cylindrical hollow tube, with end sections perpendicular to the central longitudinal axis, consisting of two sections of different diameters and symmetrical with respect to the central axis. From the end end, the larger diameter portion on the outside has an annular ledge. To install the phototube on the photo-video output of the trinocular nozzle, it is equipped with a sleeve.

The sleeve for installing the phototube on the photo-video output of the trinocular nozzle is a relatively short hollow tube, the inner diameter of which corresponds to the outer diameter of the phototube, namely, its portion of a smaller diameter. One of the ends of the sleeve is bounded by two surfaces, internal and external, and has a through cylindrical hole, the central axis of which coincides with the central axis of the sleeve. The diameter of this hole corresponds to the outer diameter of the eyepiece, which is installed in this hole. The inner surface of the end face of the sleeve has the form of a flat ring located perpendicular to the axis of the sleeve and is a reference for the phototube when it is installed. The end outer surface forms a protrusion for installing the sleeve in the socket of the trinocular nozzle. The lower portion of the outer lateral surface of the sleeve adjacent to the aforementioned end protrusion of the sleeve may be threaded to install the sleeve in the socket of the trinocular nozzle using a threaded connection.

The length of the phototube is equal to the distance from the reference plane of the microscope eyepiece to the plane of the exit pupil of the microscope eyepiece.

The transverse dimensions of the device are determined by the sizes of the connected parts of the existing devices and provide their easy and stable connection.

Figure 1 presents a transverse section of the phototube when installing it on the eyepiece of the microscope; figure 2 - the same when installing the phototube on the photo-video output of the trinocular nozzle.

A phototube is a monolithic cylindrical hollow tube consisting of a section 1, a smaller diameter and a section 2, a larger diameter, having one common central axis, with respect to which the construction of the phototube is symmetrical.

The junction of sections 1 and 2 has the form of an annular ledge. The inner plane of the annular ledge serves to fix the position of the retractable eyepiece of the camera when shooting a micro-object. For a more stable fixation of the camera in the working position at the end of the phototube at the end of section 2 from the outside there is an annular ledge 3.

To install the phototube into the nest of the trinocular nozzle, it is equipped with a sleeve 4 (Figure 2). The sleeve 4 is a relatively short cylindrical hollow tube, the inner diameter of which corresponds to the outer diameter of the portion 1 of the phototube. One end of the sleeve 4 is open for installation of a phototube, and the other is bounded by two surfaces with a through cylindrical hole 5 passing through the thickness of the body formed by these surfaces. The axis of the sleeve 4 and the holes 5 match. The diameter of the hole 5 allows you to install an eyepiece into it. Due to the difference in the diameters of the sleeve and the end hole 5, the inner surface of the end face of the sleeve 4 is made in the form of a ring. This annular ledge serves as a support for the phototube during its installation. The outer end of the sleeve 4 has a protrusion 6, repeating the contour of the socket for the photo-video output of the trinocular nozzle. The outer surface of the sleeve 4 adjacent to the above end of the sleeve has a thread 7 for fixing the sleeve 4 in the socket of the trinocular nozzle using a threaded connection.

In preparation for shooting the studied object, a phototube is put on the microscope eyepiece and its end face 1 is installed

on a supporting surface located around the eyepiece tube of the microscope.

The lens of the digital camera prepared for shooting is introduced into the internal cavity of the phototube section 2. In this case, the lens with its extreme outer surface rests on the inner annular ledge connecting the sections 1 and 2 of the phototube, and the body of the digital camera rests on the end outer ledge 3 of the phototube.

After giving the observed object a better angle and size, pointing the necessary clarity of the image, they shoot.

When using a trinocular nozzle under a microscope, a sleeve 4 is inserted into the photo-video output socket, aligning hole 5 with the hole of the trinocular nozzle socket and the sleeve is fixed in the above socket using a threaded connection. Then, an eyepiece is inserted into the hole 5 of the sleeve 4 and a phototube is coaxially put on it and mounted on the inner annular ledge of the sleeve 4.

The size of the inner diameter of the sleeve 4 and its length make it possible to reliably install a phototube in it without the possibility of lateral displacement relative to the central axis without any additional fastening devices.

Next, install a digital camera, as when installing a phototube on the eyepiece of the microscope, and shoot as described above.

The inventive solution is a simple and effective way to combine digital cameras with light-optical microscopes, for example, such as a stereoscopic microscope MBS-10, or research microscopes Ampleval (Zeiss) and Studar (PZO).

The phototube can be applied using any digital camera that has the ability to zoom, i.e. zooming objects.

The proposed phototube has the dimensions optimal for its use on specific equipment, can be easily made of light metal, for example, aluminum grade D16T,

easy to use, has a small size, smooth surface, ergonomic and does not require operating costs.

When selecting the optimal length of the phototube, the condition was used under which the actual image of the micro-object is in the plane of the matrix of the digital camera and is recorded on its monitor.

In the manufacture of the inventive phototube, the transverse dimensions of the device are made with the possibility of easy sliding of the device and the sleeve along the inner and outer surfaces between themselves, as well as the parts of the equipment to be connected that interact with them.

The application of the proposed solution is an inexpensive, affordable and effective means of connecting digital cameras with microscopes to document the morphology of microscopic objects, allows you to expand the possibilities for research, to perform high-quality shooting of the object and eliminate significant costs associated with this.

Claims (3)

1. A phototube for mounting a digital camera on one of the eyepieces of a microscope or on the photo-video output of a trinocular nozzle, characterized in that it is a monolithic cylindrical hollow tube, with end sections perpendicular to the central longitudinal axis, consisting of two sections of different diameters and symmetrical with respect to the central axis, from the end end, the larger diameter portion on the outside has an annular ledge for mounting a digital camera when installing a phototube on the photo-video output of a trinocular nozzle, It is equipped with a sleeve. 2. The phototube according to claim 1, characterized in that the sleeve is a relatively short hollow cylindrical tube, the inner diameter of which is comparable to the outer diameter of the phototube, namely, its portion of a smaller diameter, one of the ends of the sleeve is bounded by two surfaces, internal and external, and has a through cylindrical hole, the central axis of which coincides with the central axis of the sleeve, the diameter of this hole corresponds to the outer diameter of the microscope eyepiece installed in this hole, internal on top the spine of the end face of the sleeve has the form of a flat ring located perpendicular to the axis of the sleeve and is supportive for the phototube when it is installed, the end outer surface forms a protrusion for installing the sleeve in the socket of the trinocular nozzle, while part of the side outer surface of the sleeve adjacent to the outer end of the sleeve can have a thread for installing the sleeve in the socket of the trinocular nozzle using a threaded connection. 3. The phototube according to claim 1, characterized in that the length of the phototube is equal to the distance from the reference plane of the microscope eyepiece to the plane of the exit pupil of the microscope eyepiece.