HRP20090091A2 - Ring illuminator with maximum light intensity - Google Patents

Abstract

Ring illuminator with a maximum intensity of light consisting of two or more light sources. Turning the adjusting ring changes the angle of the optical axis of the light source to the axis of the illuminator, ie the angle θ. Thanks to the angle adjustment mechanism θ, the illuminator makes it easy to generate the maximum intensity beam at different distances. Light sources can be light emitting diodes of different wavelengths, thus enabling the use of illuminators for illumination in the visible part of the light spectrum as well as in the ultraviolet and infrared parts of the spectrum. In this way, the illuminator can be used to stimulate fluorescence and fluorescence macro photography.

Description

The field to which the invention relates

The invention relates to a ring illuminator that maximizes the intensity of illumination, i.e. to an object illuminator, whether it is used as an independent device or as part of an optical device. An optical device can, for example, be a camera or camera.

Technical problem

When recording or observing objects or phenomena where an illuminator is used, the problem of lighting the observed objects appears when they are of different sizes. Given that the size of the observed object also affects the distance from which the object will be observed, different sizes of observed objects also bring the problem of lighting the object at different distances. This is especially pronounced when the object is viewed under fluorescent light or a fluorescent image of the object is taken. In this case, a high intensity of exciting light with which the object is illuminated, which has a different wavelength than fluorescent light, is required. The problem arises when shooting small objects at short distances in macro mode, as well as when switching to shooting distant larger objects. Existing illuminators adjusted to work at short distances (close-up) are unsuitable for illuminating larger objects at a greater distance. Illuminators with a fixed beam diameter cannot be used when observing and recording the fluorescence of near and far objects. Furthermore, the problem with the devices that were used until now to illuminate buildings was their complexity in manufacturing and the costs of manufacturing such devices. Precisely because of their complexity, the application of such devices used to be complicated and did not facilitate work with the optical instruments for which such devices were used.

State of the art

In the current state of the art, there is a large number of ring illuminators in different designs, different possibilities and different purposes and applications. Below is an overview of patent applications and patents relevant to this patent.

Patent JP9147089 describes a ring illuminator in which the light sources are located on a perforated elastic ring that is sandwiched between two rigid rings that fit into each other. The vertical movement of the outer ring bends the elements of the perforated elastic ring and thus changes the angle of the light sources fixed on the elastic ring. The invention of the mentioned document provides an illuminator that can illuminate the surface of the object at different angles in relation to the optical axis. The largest deviation that the optical axis of the illuminator can have in relation to the optical axis of the optical device is when the said optical axes are parallel. The problem with the aforementioned illuminator is that by moving the outer ring in relation to the inner ring, the lighting angle is shifted synchronously with the light sources, but such an illuminator cannot reliably maintain a certain lighting angle during the entire recording or observation of the object. Furthermore, as all light sources move synchronously and at the same angle in relation to the illuminator, the incident light of these light sources does not close the same angle on the illuminated object, because depending on their position on the illuminator, the light sources send light at the same angle but also from the same distance between their bundles. This device does not provide for the use of clusters of light sources. Also, this type of device does not offer the possibility of a different angle for each of the light sources.

Patent US 20040212996 describes a device consisting of a circular support on which light-emitting diodes are placed, arranged in several concentric rings. The edge diodes of the device can move together with the movement of the outer ring, and in this way the edge light-emitting diodes can be influenced by the outer ring and move together with its tilting.

Patent WO2006099834 relates to an illuminator for optical, medical, and especially reflective microscopes. With this device, the angle of incidence of light can be changed in relation to the optical axis of the illuminator by changing the angle of the light elements using the relative displacement of the adjustment ring. The construction of the subject illuminator does not allow placing individual light beams in a position in which they are parallel to the optical axis of the device, and therefore this illuminator does not allow for the illumination of objects at greater distances.

Patent US 6454437 describes a device consisting of a circular support on which light-emitting diodes are fixed. The light from these diodes is directed by a Fresnel lens. The illuminator is efficient for lighting at a wide angle.

Patent US20040175027 describes an illuminator with seven LED rings, each of which has a certain different angle to the axis. Each ring emits a different wavelength. Thanks to this, it is possible to achieve different visual effects. By choosing an individual ring, different angles of the output beam are achieved.

Patent JP2003315678 describes a device that is composed of LEDs fixed around the optical axis. Each LED has its own router that directs the emitted light and directs it to a specific point on the optical axis.

Patent JP2004361552 describes a ring illuminator where the LEDs are placed on an inclined plane relative to the optical axis of the illuminator. The arrangement of the light sources enables a homogeneous distribution of illumination.

When stating the state of the art, the terms as stated in the state of the art were used. However, as far as it was possible, an attempt was made to use the expressions that will be used in the description of the subject invention.

Presentation of the essence of the invention

The patent in question tries to solve the problem of lighting objects of different sizes as well as the problem of lighting objects at different distances without the need to use different illuminators that are specific for each individual lighting method. The mentioned problem occurs in the case when the illuminator is used independently as well as when the illuminator is used together with optical bodies to illuminate the observed or recording objects.

The term "illumination" in the subject invention implies illumination by emitting electromagnetic radiation in the ultraviolet part of the spectrum (UV radiation), in the visible part of the spectrum (visible light) and in the infrared part of the spectrum (IR radiation).

For example, when using different optical devices, there is a need for better lighting of the object or object. As the objects that are illuminated are not always the same size, it is necessary to observe them from different distances with the same optical device. This sometimes requires the optical device to be used at medium distances when viewing or recording larger objects and at very short distances when viewing or recording small objects. Images obtained from such a small distance are called macro images in the photography technique (optics).

Given that working with optical devices often requires a change in the distance from the object, it is necessary to adapt the method of lighting the object to such a distance. In order for the illuminator to be able to be used under different operating conditions, it was necessary to facilitate the adaptation of the light source of the illuminator to different operating conditions.

The term "light source" in the subject invention implies sources of electromagnetic radiation that emit visible light, ultraviolet radiation, and infrared radiation.

The term "light" in the subject invention implies electromagnetic radiation in the ultraviolet part of the spectrum (UV radiation), the visible part of the spectrum (visible light) and in the infrared part of the spectrum (IR radiation).

The term "angle θ" in the present invention means the angle at which the optical axis of the light source intersects the optical axis of the illuminator.

The term "individual light source" in the present invention implies such a light source where one light source is attached to one light source base.

The term "cluster of light" in the present invention implies such a light source where several light sources are attached to one light source base. Given that in some state-of-the-art documents the term "cluster of light" was used instead of the term "cluster of light", it should be noted that the term "cluster of light" in the subject invention includes both of the above terms in the state of the art.

The term "optical axis of the illuminator" in the subject invention implies the optical axis of the ring illuminator maximizing the intensity of illumination.

The term "beginning of the slit" in the present invention means the point on the slit that is closest to the optical axis of the illuminator.

The term "end of the slit" in the present invention means the point on the slit which is farthest from the optical axis of the illuminator.

Furthermore, in practice it has been shown that the illuminators should be able to receive a large number of light sources that would illuminate the observed object. When applying a large number of light sources, whether it is about placing them in clusters or placing several individual light sources in several different rows, there is a problem when you want to manage them in such a way that all bodies are directed to a certain point of observation or recording. Thus, with a large number of light sources, good illumination is obtained, but due to their poor mutual position, the intensity of the light on the object being illuminated is lost. Namely, a small number of light beams from the light source outside the point of illumination scatters the light on the surrounding area and thus reduces the concentrated light intensity (beam diameter, spot). Therefore, it was necessary to find an illuminator whose construction would enable the simple installation of a large number of light sources, whether it is about clusters of light sources or the placement of several individual light sources in several different rows, and would enable the smooth change and adjustment of light source angles. This would ultimately enable the object to be illuminated with maximum light intensity regardless of whether the object is located at a medium or macro distance from the subject invention. Also, the construction of the subject invention enables easy achievement of maximum light intensity when changing the distance and size of the object.

The present invention attempts to solve the above-mentioned problems that have arisen in the prior art. The ring illuminator of the subject invention refers to an illuminator of concentrating action with the possibility of concentrating light intensity at different distances. It is a so-called ring illuminator with maximum intensity of illumination that uses individual light sources or clusters of light sources. The subject invention makes it possible to easily achieve the maximum intensity of illumination during observation, photography and recording from macro to medium distances by adjusting the size of the diameter of the beam to the size of the object, thereby enabling maximum intensity of illumination at any of the specified distances.

The subject invention provides a ring illuminator maximizing the intensity of illumination with two or more light sources, which contains:

- the base ring that represents the stationary part of the ring illuminator maximizing the intensity of illumination, where the base of the light source (hereinafter referred to as the "base") of each light source is attached to the base ring via a movable yoke, thus attaching each of the light sources to the ring illuminator, and at the same time enabling each of the light sources to change the angle of the optical axis of the light source in relation to the optical axis of the illuminator - angle θ. The movable yoke is connected to the base in such a way that the position of the light source within the subject invention and the inter-room position of two or more light sources in the subject invention cannot be changed, while at the same time it is possible to change the angle θ of each light source in such a way that each source can rotate around its axis.

- an adjusting ring that contains two or more slots and is located between the base ring and the base, so that each outgrowth of the base of the light source (hereinafter referred to as "the outgrowth of the base") that is attached to the base is placed in one of the slots of the adjusting ring, where are the outgrowths of the base movable within the slot, so that by rotating the adjusting ring with slots around the optical axis of the illuminator, the outgrowths of the base change their position within the slot, and the position of the outgrowth of the base in the slot determines the angle θ, i.e. the angle at which the optical axis of the light source intersects the optical axis of the illuminator. The shape of the slits and their position on the adjusting ring determine the change of angle θ when rotating the adjusting ring around the optical axis of the illuminator. This means that the shapes of the slits and their position on the adjusting ring determine all the angles θ that each of the light sources can achieve when using the subject invention.

The base ring and the adjusting ring of the present invention are mechanically connected. Various possibilities of mechanical connection of the said rings are known to an average person skilled in the field of this invention. It is desirable that the adjusting ring is rotated around the optical axis of the illuminator by means of a rotation mechanism.

The connection between the turning mechanism and the adjusting ring is such that by turning the mechanism, the adjusting ring with slots rotates around the axis of the illuminator. Therefore, the change of the angle θ is achieved by starting the turning mechanism, which turns the adjusting ring. By rotating the ring, the slots on the adjusting ring are also rotated, which causes the position of the footplate to change within each of the slots. Changing the position of the foot shoots causes an angular movement of the light source. Given that the relationship between the movable yoke and the light source does not allow the light source to change its position within the subject invention, the light source changes only the angle θ. The angle θ will depend on the change in the position of the foot shoots within the slot.

The shape of the slot determines the ratio of the angle of rotation of the adjusting ring around the axis of the adjusting ring and the angle θ. The shape of the slot is such that it enables the position of the foot shoots to be continuously changed within the slot. The position of the foot shoots can be changed along the entire length of the slot, i.e. from the beginning of the slot to the end of the slot without stopping.

It is desirable that the subject ring illuminator of maximizing illumination intensity contains light-emitting diodes or clusters of light-emitting diodes as light sources. It is desirable that said light sources emit visible light.

Furthermore, it is preferable that the light sources on the illuminator in question are arranged circularly and symmetrically to the optical axis of the illuminator, maximizing the intensity of the illumination. It is desirable that the slits on the adjusting ring are of such a shape and that they have such a position in relation to the adjusting ring that during use all light sources close the same angle with the optical axis of the illuminator at all times (angle θ).

In order for the angle θ of all light sources to be uniformly changed from the minimum to the maximum value by rotating the adjustment mechanism, i.e. the adjustment ring, it is preferable that the slits are spiral-shaped, that is, that they are spiral slits. With such spiral slits, a more precise control of the illumination intensity is possible at larger angles θ, that is, at smaller distances from the object being illuminated, which is otherwise more difficult to achieve than control at smaller angles θ.

With the mechanism of the subject invention, it is possible to achieve different angles of the optical axis of the light source in relation to the optical axis of the illuminator. More precisely, the angle θ can take any value from the minimum, which is 0° and where the optical axis of the radiation source is parallel to the optical axis of the illuminator, to the maximum value. The maximum value of the angle is determined by the structure of the light source and the base used in each use of the subject invention, and by the shape and position of the slot on the adjusting ring.

The angle θ of each of the light sources in the subject ring illuminator of the maximizing intensity of illumination is regulated by the position of the outgrowth of the base of each of the light sources in the slot of the adjusting ring. When all said slits have the same shape and are axially symmetrically distributed on the adjusting ring, then all the angles θ of the light source of the subject invention change synchronized according to that particular shape of the slit on the adjusting ring of the subject invention. In this way, all light sources of the illuminator change the angle θ according to a predetermined shape.

One of the advantages of the subject invention is that it enables the adjustment of the maximum possible intensity of illumination for macro and medium distances from the object. The size and distance of the beam diameter from the ring illuminator depends on the angle θ of each light source.

Given that the change in the angle θ is determined by the shape and position of the slot on the adjusting ring, handling the subject invention is simple and precise.

The subject illuminator may include an adjustment ring that is separable from the subject device. In this way, the device can be easily changed by adjusting the rings of different slot shapes that determine the angle of the optical axis of the light source in relation to the optical axis of the illuminator. For example, an adjusting ring can be inserted in which the slits determine that each light source has a different angle of incidence on the illuminated surface of the object, or that one third has the same angle of incidence, and that all others are different. In this way, the subject invention can be used, for example, when there is a need for asymmetric lighting of objects.

As the requirements for lighting the objects of observation, photography and recording are individual and sometimes need to be adapted to the special requirements of a certain profession, and given that the subject ring illuminator maximizing the intensity of illumination can be easily disassembled, the adjusting ring can be changed even during use in order to changed the lighting regime.

One of the goals of the invention is a device that will enable illumination when observing, photographing and recording objects, especially when a high intensity of primary or excitation light is required. This particularly applies to the use of the subject invention in observing, photographing and recording fluorescent images of biological objects in situations of recording small objects from close range with high magnification, when it is necessary to excite fluorescence in the biological object by lighting with the subject invention. In this case, it is desirable that the light sources of the ring illuminator with the maximum intensity of illumination can emit light in the ultraviolet part of the spectrum.

Also, the light sources of the ring illuminator maximizing the intensity of the illumination can, if necessary, emit light in the infrared part of the spectrum.

The adjusting ring of the present invention is a simple slotted plate. Given that the said plate with slots is flat, in production it can be produced by any suitable method of plastic deformation (punching), alloy or polymer casting procedures or machining procedures (milling, eroding) and does not require complicated and expensive manufacturing, e.g. on numerical controlled machines (CNC), but it can also be made that way. This simplicity and cost-effectiveness of the production of the subject invention represents another of its advantages compared to the state of the art.

Brief description of the drawing

The drawings are included in the description of the invention and form an integral part thereof. The drawings show the construction, composition and mode of operation of the ring illuminator maximizing the intensity of illumination.

Drawings 1a and 1b. - clarify the geometrical relationships of the light beams of each of the light sources and the total beam of the ring illuminator maximizing the illumination intensity on the object of observation, for example two different angles of the axis of the light source and the axis of the illuminator.

Drawing 2 - shows a plan and a side view of one of the ways of realizing the invention with light sources

Drawings 3a, 3b and 3c - show the outline and side view of one of the ways of realizing the invention and the position of the light source determined by the selected angle θ.

Detailed description of one of the ways of realizing the invention

A ring illuminator of maximizing illumination intensity (Drawing 2 and Drawings 3a, 3b and 3c) contains two or more light sources (1), whether they are individual light sources or clusters of light. It is desirable that each of the light sources (1) contains at least one light-emitting diode, a router (2) and a base (3) and an extension of the base (7). Each of the legs (3) is attached via a movable yoke (4) to the base ring (9) of the invention in question, which is the stationary part of the ring illuminator maximizing the light intensity. In this way, the movable yoke (4) attaches each of the light sources (1) to the base ring (9), enabling them to move simultaneously in an angle. The adjusting ring (8) of the present invention is located between the base ring (9) and the base (3). The adjusting ring (8) further contains slots (6). On the base (3) is attached a branch of the base (7) which passes through the slot (6) on the adjusting ring (8).

In this embodiment of the present invention, the slits (6) on the adjusting ring (8) are spiral slits (6) in such a way that the parts of the slits closer to the optical axis of the illuminator (5) are more curved than the parts of the slits that are further away from the optical axis of the illuminator ( 5). Since the protrusions of the foot (7) are not immovably fixed on the adjusting ring (8), by rotating the adjusting ring (8) with spiral slots (6) around the optical axis of the illuminator (5) by means of the rotation mechanism (13), the protrusions of the foot (7) can be found anywhere along the spiral slot (6) in which they are located. Therefore, by rotating the adjusting ring (8) around the optical axis of the illuminator (5), the angle of the optical axis of each light source relative to the optical axis of the illuminator (5) is forced to change, i.e. changing the angle θ.

In this embodiment of the invention, the turning mechanism (13) is an external toothed ring. Therefore, in this embodiment of the invention, the adjustment ring (8) is rotated by manual rotation of the outer toothed ring (13).

It is preferable that the ring illuminator maximizing the illumination intensity is fixed to the optical device via the base ring (9) in such a way that the optical axis of the illuminator (5) and the optical axis of the optical device coincide. It is also preferable that such an optical device is a camera. The connection between the camera and the subject invention can also be achieved via a support (10) on which there is a hole (11) for attaching to the camera. A handle with a switch (12) for turning on the subject invention is fixed on the support (10). The handle with the switch (12) enables easier handling of the subject invention when it is connected to the camera.

In this way of realizing the invention, all light sources close the same angle with the axis of the optical illuminator (5) and the lens of the optical device at all times. By rotating the adjusting ring (8) around the optical axis of the illuminator (5), the angle θ changes from the minimum to the maximum value. This way of realizing the invention is particularly suitable for macro photography, and especially for macro photography where a ring illuminator of maximizing illumination intensity is used to excite fluorescence.

Figure 1a shows the action of the ring illuminator maximizing the intensity of illumination at the maximum angle of the optical axis of each of the light sources and the axis of the illuminator (5), i.e. the angle θmax. In other words, the optical axis of each of the light sources is in this case maximally deflected from the optical axis of the illuminator (5) Cross-sections of the beams of individual light sources with the vertical plane are elongated ellipses. The sum of these individual elliptical beams gives a resultant beam that is star-shaped. A central circle with a diameter dmax of maximum intensity is observed at a distance lmin from the plane of the light source.

Drawing 1b shows the situation with one of the possible angles θ. It is observed that the cross-sections of the beams of individual light sources are less elongated. The diameter of the resultant beam is less deformed and increased compared to drawing 1a. Also, the vertical plane is at a greater distance than the plane of the individual sources. A central circle with a diameter d of maximum intensity is observed at a distance l from the plane of the light source.

From drawings 1a and 1b, when the angle θ changes, the size of the beam diameter d and its distance l from the plane of the individual illuminator sources can be observed.

When a ring illuminator of maximizing illumination intensity is used to excite fluorescence, it is possible to choose the emission wavelength of individual sources in a wide range from 255 nm to 1,800 nm, that is, this range extends to the available wavelengths of existing light-emitting diodes. In such cases, the subject invention would be used to excite fluorescence in a biological sample by illumination, which serves to observe, photograph and record fluorescent images of biological objects in situations of imaging small objects at short distances with high magnification.

When using fluorescence excitation, it is also possible to use white light. It is possible to combine the wavelengths of the partial sources so that the resultant beam diameter produces white light of a certain color temperature.

Adjusting the maximum intensity of illumination

Depending on the shooting distance, the diameter of the illuminator beam is adjusted so that at a certain distance it gives the maximum intensity of illumination.,.

Drawings 3a, 3b and 3c show the operation of the subject invention

Drawing 3a shows the direction of the light source (1) in the basic position. The adjusting ring (8) is in the rightmost position, and the protrusions of the feet (7) in the slots (6) are in the position closest to the axis of the illuminator (6). The axes of the light source are at a minimum deviation in relation to the optical axis of the illuminator (5). In this case, the minimum deviation of the axis of the light source is the one in which the axis of the light source is parallel to the axis of the illuminator (5), i.e. the angle θ is 0°. In this position, the subject invention is adjusted for recording and observing at maximum distances.

Drawing 3b shows the situation when the adjusting ring (8) is rotated to one of the intermediate positions in relation to the ends of the spiral slots (6). The protrusions of the feet (7) are located in the middle of the spiral slits (6), and the light sources (1) cover half of the maximum angle θ. This is the optimal position for shooting and observing at medium distances.

Drawing 3c shows the situation when the adjusting ring (8) is turned to the extreme left position. In this case, the protrusions of the foot (7) in the slots (6) are located in the position farthest from the axis of the illuminator (5). The axes of the light source close the maximum angle with the axis of the illuminator (5). In this case, the light diameter of the beam is closest to the camera and is determined with the minimum diameter and the maximum possible intensity. This position is optimal for macro photography, especially when high intensities are needed, as in macro fluorescent photography.

Claims (13)

1. A ring illuminator of maximizing illumination intensity containing two or more light sources, characterized by the fact that it contains: the base ring (9) which is a stationary part of the ring illuminator maximizing the intensity of illumination, where the foot (3) of each of the light sources (1) is attached to the base ring (9) via a movable yoke (4), thus attaching each of the light sources for the ring illuminator, while at the same time enabling each of the light sources to change the angle of the optical axis of the light source in relation to the optical axis of the illuminator (5), i.e. the angle θ; adjusting ring (8) containing two or more slots (6) and located between the base ring (9) and the foot (3), so that each leg of the foot (7) attached to the foot (3) is placed in one from the slot (6) of the adjusting ring (8), where the protrusions of the foot (7) are movable inside the slot (6), so that by rotating the adjusting ring (8) with slots (6) around the optical axis of the illuminator (5), the position of the protrusion of the foot changes (7) inside the slot (6) and that the position of the outgrowths of the foot (7) in the slots (6) determines the angle at which the optical axis of the light source intersects the optical axis of the illuminator (5), i.e. the angle θ. 2. A ring illuminator maximizing the intensity of illumination according to claim 1, characterized in that the adjusting ring (8) is rotated around the optical axis of the illuminator (5) by means of a rotation mechanism (13). 3. A ring illuminator of maximizing light intensity according to claims 1 and 2, characterized by the fact that the light sources (1) are arranged circularly and symmetrically on the optical axis of the illuminator (5). 4. A ring illuminator maximizing light intensity according to claims 1 to 3, characterized by the fact that the slits (6) are of such a shape and have such a position in relation to the adjusting ring (8) that during use all light sources (1) close at all times the same angle with the optical axis of the illuminator (angle θ). 5. Ring illuminator maximizing the intensity of illumination according to claims 1 to 4, characterized in that the slits (6) on the adjusting ring (8) are spiral slits (6) in such a way that the parts of the slits closer to the optical axis of the illuminator (5) are more curved than the parts slits that are further away from the optical axis of the illuminator (5). 6. A ring illuminator maximizing light intensity according to claims 1 to 5, characterized in that the adjusting ring (8) is separable from the device and that adjusting rings (8) of different slot shapes can be changed. 7. A ring illuminator maximizing illumination intensity according to claims 1 to 6, characterized in that the illuminator is fixed to the optical device via the base ring (9) in such a way that the optical axis of the illuminator (5) and the optical axis of the optical device coincide. 8. A ring illuminator maximizing lighting intensity according to claims 1 to 7, characterized in that each of the light sources (1) contains light-emitting diodes or clusters of light-emitting diodes. 9. A ring illuminator maximizing lighting intensity according to claims 1 to 8, characterized in that the light sources (1) emit visible light. 10. A ring illuminator maximizing illumination intensity according to claims 1 to 8, characterized in that the light sources (1) emit light in the ultraviolet part of the spectrum. 11. A ring illuminator of maximizing illumination intensity according to claims 1 to 8, characterized in that the light sources (1) emit light in the infrared part of the spectrum. 12. The use of a ring illuminator maximizing the intensity of illumination as specified in claims 1 to 11, characterized in that it is used for illumination during observation, photography and recording of objects. 13. The use of a ring illuminator maximizing the intensity of illumination as specified in claim 12, characterized by the fact that it refers to the excitation of fluorescence in a biological sample by illumination, which is used for observing, photographing and recording fluorescent images of biological objects in situations of recording small objects at short distances with by a large increase.