西班牙专利ES2632108A1 Procedure for the design of a pair of ophthalmic lenses and device for optical measurements (Machine

专利PDF首页>>西班牙专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
Design procedure of a pair of ophthalmic lenses and device for optical measurements. The method comprises: determining a distance and placing an object (100) at said distance; placing a frame (4) of reference to the user; for each eye: keep it open and cover the other eye; placing a screen (5, 6) with a through hole (520, 620) in front of the eye; moving the position of the hole (520, 620) until the user sees said object (100) looking through the hole (520, 620), so that said object (100) is centered in the available field of view; discover both eyes; adjust the positions of the holes (520, 620), to achieve binocular vision and design each lens (510, 610) according to said position. The device (1) comprises a frame (2) to which, for each eye, a first plate (51, 61) with a vertical groove (53, 63) and a second plate (52, 62) with a groove are movable. Horizontal (54, 64). So that when the slots overlap, a pinhole is formed (55, 65). (Machine-translation by Google Translate, not legally binding)
公开号:ES2632108A1
申请号:ES201730494
申请日:2017-03-30
公开日:2017-09-08
发明作者:Julio VILLAVERDE ROSENDE
申请人:Merindades Vision S L；Merindades Vision Sl；
IPC主号:

专利说明:

Field of the Invention
The invention is in the field of ophthalmic lenses.
More specifically, the invention relates to a method of designing a pair of ophthalmic lenses, each lens corresponding to a user's eye.
The invention also relates to a device for optical measurements, comprising a frame with a mounted position in which a user wears said device in front of the eyes, defining an inner side facing said eyes, and an outer side opposite said internal side, said device provided with first mounting means.
State of the art
In the field of corrective lenses, the so-called monofocal lenses are intended to correct a user's visual defects, usually for a specific distance of vision. There are also bifocal glasses, with two vision regions (for example, one for far vision and one for near vision) and two optical centers, or even multifocal lenses for multiple viewing distances. A particular case is the so-called progressive lenses that are generally designed for distance vision and near vision, and in which there is an intermediate zone between the optical center for distance vision and the optical center for near vision that changes from gradually, which allows adapting to different intermediate distances. In this case, the horizontal distance between the far and the near optical center is known as inset, while the vertical distance is known as aisle length.
In relation to the lenses, the focal length or focal length of a lens is the distance between the optical center of the lens and the focus, also called the focal point. Focal length can take positive or negative values. Said focal point is the point where the parallel rays that cross the lens converge, in the case of converging lenses. Or an imaginary point from which the light beams that pass through the lens appear to emerge, in the case of divergent lenses. In the first case, the focal length is positive, while in the second case, the focal length is negative. The power of a lens is the inverse of the focal length, and is measured in diopters (m-1).
Thus, the prescription of the power of the lenses that allows a correct vision for the distance of vision for which the lenses are designed, is usually performed by a professional using devices and procedures common in the technique to achieve correct diopter values in each case and for each eye, obtaining a pair of lenses that are mounted on glasses.
Indeed, said professional makes measurements to a user so that he can prescribe suitable lenses for the same. In the design phase, the type of corrective lens (for example for myopia, farsightedness, presbyopia, etc.), its power (measured in diopters), as well as the optical center of said lens is determined. Note that this optical center of the lens can also be displaced to achieve an effect equivalent to a prism whose power in diopters is proportional to said distance of travel and the power of the lens. This is known as the Prentice Law.
In the known technique, the determination of the optical center is carried out in two main ways: by means of standard preset positions or through specific measurements. The first case, although it has advantages such as mass production of lenses, is not too adaptable for some users, especially if there are facial asymmetries or other types of conditions that deviate the location of the optical center with respect to said standard position. In the second case, the usual methods start from observing the location of the user's pupils when he looks at an object located at the viewing distance for which the lenses are designed. In this case, when projecting the imaginary line that joins the object with the centers of each retina, this line crosses the geometric axis of the eye and the point at which it would cross the lens can be determined, once located in its position of use in glasses
The expert will understand that in the case of bifocal, multifocal or progressive lenses, the measurement is repeated for the viewing distances required in the lenses. For the sake of clarity and brevity, in the context of this invention we will talk about a viewing distance, however, the expert may apply the same considerations in the case of bifocal, multifocal or progressive lenses.
In this way, the ophthalmic lens design methods existing in the current state of the art based on measurements are intended to determine the optimal position of the optical center of each lens for a viewing distance. As indicated above, this is mainly done from the positions of the user's pupils when looking at a reference object located at the viewing distance. However, to obtain the position of the optical centers by trigonometric rules, it is also necessary to know the specific shape of the eye and its different parts, in particular values such as the location of the fovea are necessary.
The area of the retina where the light rays are focused is known as fovea and is specially trained for color vision. Thus, directing the view towards an object means placing its optical image in the fovea. However, the position of the fovea within the eye is not aligned with its geometric axis, thus, in the art it is known as the Kappa angle to the angle between:
- a geometric axis of the eye, which crosses the geometric center of the pupil of
said eye; Y
- an optical axis of the eye, which joins the central fovea of the retina of said eye with
said point located at the viewing distance. This optical axis also receives the
Foveolar fixing shaft name. For this reason, in the known technique, instead of using the previously commented imaginary line that is based on the geometric axis, it is corrected using said Kappa angle.
Unfortunately, some of this data is very difficult or even impossible to measure live through an external user scan. In some cases these measurements would require surgical interventions or exploratory equipment not usually available in the field of optometry, such as X-ray devices, ultrasound scanners, etc. Consequently, it is usual in the art to use standard values for such data, for example, for emtrope users, a Kappa angle of about 5 ° is considered, for hypermeters up to 10 ° or more, while in myopia the Kappa angle reaches 2 °.
This impossibility of real customized measurements for each user results in a determination of the optical centers of the lenses that may not fully coincide with the user's real axes of vision. This causes the lens to be offset from the position that the user would really need. In cases where the deviation is not very large, the user can accommodate their vision, although side effects such as headaches or eyestrain may occur. In more pronounced cases, binocular vision may be lost, blurred vision, etc.
For these reasons, it is necessary to have an ophthalmic lens design procedure that allows to obtain greater precision in the location of the optical centers of the lenses, and that is adaptable to each user for whom said lenses are designed.
Description of the invention
Some concepts common to the invention to which this document refers are described below. Unless otherwise indicated, it will be understood that the addresses are relative to the user when he is in an upright position, in this sense, the horizontal direction is that which goes from the right side to the left side of the user or vice versa. The vertical direction is that parallel to the user's vertical.
References to far vision or near vision should be understood as referring to situations in which a user looks at a point located at a distant distance or at a close distance, respectively. On the other hand, when talking about binocularity, conditions of binocularity or binocular vision, it should be understood that the user's brain is able to fuse the images of both eyes, so that a perception of depth is reached. On the contrary, we speak of diplopia, dissociated vision, dissociation conditions or vision in dissociated form, when the images formed in each eye fail to merge, so that a perspective image is not achieved.
In binocular vision, the fovea of one eye corresponds to a small area centered on the fovea of the other eye called the Panum Area. Thus, a small area of the other eye corresponds to each point of the retina of one eye. Thus, if one eye deviates, the patient will not present diplopia while the image falls within the Pánum Area.
It is known as fixing disparity to the difference in alignment of the visual axes that allows sensory fusion. When the magnitude of the disparity of fixation is small, the object is projected into the fusional areas of Pánum, while if the disparity of fixation is large we can face anomalous causes or visual problems.
The deviation can occur in both one eye and both and can be physiological or the result of stress on binocular vision. It is known as foria associated with the power of the prism necessary to neutralize said fixation disparity. In this sense the measurements of fixation disparity and associated foria are equivalent because one implies the other.
For its part, ophthalmic lenses are intended to be mounted on glasses, fastened by a frame. Thus, the position of use is determined by said frame, the shape of the lenses and the angles in which they are in relation to the user, the main ones being the pantoscopic angle (with respect to the vertical) and the angle of galbe (respect to the horizontal). In the art, the usual way of determining the position of an optical center comprises two distances: a horizontal distance referenced to the nasal bisector plane, this being a vertical plane that divides the bridge of the user's nose; and a vertical distance. Said vertical distance corresponds to the height with respect to the lower end of the lens, said lower end being located on a vertical line centered on said horizontal distance. The expert will understand that these measures should be considered in the position of use of the lenses in the frame.
The purpose of the invention is to provide a design procedure for a pair of ophthalmic lenses of the type indicated at the beginning, which allows solving the problems raised above.
This purpose is achieved by a design procedure for a pair of ophthalmic lenses of the type indicated at the beginning, characterized in that it comprises a measurement step comprising the following steps:
[a] determine a viewing distance and place a reference object at a point located at said viewing distance;
[b] place a reference frame to a user, configured to determine a position of use of said lenses;
[c] for a user's first eye:
[1] keep said eye uncovered and cover the other eye;
[2] placing in front of said eye a screen corresponding to said eye provided with a through hole corresponding to said eye;
[3] move the position of said hole until the user sees said object looking through said hole, so that said object is centered in the field of vision that allows said hole;
[d] repeat steps [c.1] to [c.3] for a second eye;
[e] discover both eyes;
[f] in case the user sees two areas corresponding to said holes corresponding to said first eye and said second eye in a dissociated way to adjust the position of said holes, so that both images are fused, thus achieving binocular vision;
[g] for each hole corresponding to an eye and a lens, make a measurement of the position of said hole with respect to said position of use of said lens; Y
[h] design each lens corresponding to an eye for said viewing distance according to said position of said hole corresponding to said eye.
In this way, the measurement starts from a subjective observation by the user, so that the line that joins each through hole with the reference object coincides with the foveolar fixing axis. Thus, it is not necessary to make any assumption of the position of the fovea in the eye. Indeed, the point at which said foveolar fixation axis crosses said position of use where the lens will be indicates the location of the optical center of the lens for said viewing distance. This results in a lens design with a much more precise configuration, and customized for that user. The expert will understand that the procedure can be repeated for different viewing distances, for example, in the case of bifocal, multifocal, or progressive lenses. Likewise, steps [c] to [f] can be repeated to achieve a progressive adjustment for the same viewing distance, so that the position of the holes is adjusted iteratively.
In the context of the invention, unless otherwise indicated, the step of placing a reference object at a point located at said viewing distance preferably comprises placing it at said distance and in a preferential position of use by the user for said viewing distance. For example, for distant vision it is usually customary for the user to look straight ahead at eye level. However, close vision is usually associated with tasks such as reading a book. In this case the object is preferably placed in relation to the user in the place where said book would be located. Although this effect is more common in near vision, there are also users who in far vision tend to tilt the head and / or perform a rotation of the eyes. This methodology has the advantage of greater customization of the lenses for the user, since the design takes into account the use and preferential positions of the user who will use said lenses.
The expert will understand that the fact of covering one eye can be done in different ways, although preferably it is understood that the user himself closes said eye, covering it with his eyelids. Likewise, said screen preferably comprises one or several overlapping plates so that the through hole of each screen communicates both sides of the plates. In addition, the screen is preferably non-transparent, so that it is easier for the user to determine what part of the vision is contained in said hole. In other preferred embodiments, the screen is transparent, which allows the professional performing the measurements to observe the user's eye, which is useful for an ophthalmological diagnosis, as well as to facilitate the user to find the reference object. On the other hand, said hole is preferably a pinhole hole although no collision holes are excluded.
In relation to the reference object, this preferably comprises a central element, horizontal guides and vertical guides. Preferably said guides are a horizontal ruler and a vertical ruler, or a grid. In this way, it is easier for the user to center the viewing point through the hole, which improves the accuracy of the design.
On the basis of the invention defined in the main claim, preferred embodiments are provided whose characteristics are set out in the dependent claims.
Preferably, each of said holes is a pinhole, with a diameter preferably between 0.2mm and 5mm, more preferably between 0.4mm and 0.6mm, even more preferably 0.5mm. Said hole can have different geometric shapes, not just circular. In this sense, diameter is spoken in a broad sense, corresponding to the straight segment of greater length between those that join two points of the perimeter of the hole through the center of said hole. Very large diameters have the disadvantage of loss of precision, while very small diameters make vision difficult and produce unwanted diffractions. It has been proven experimentally that these values have favorable viewing conditions without losing excessive precision.
Preferably, for each eye, said screen for said eye comprises a first plate, provided with a through vertical slot, and a second plate, overlapped with said first plate and provided with a through horizontal slot, so that said pinhole is formed by the superposition between said vertical groove and said horizontal groove, and in which steps [c] to [f] are broken down in one step to determine the horizontal position comprising the following steps:
[c ’] for a user's first eye:
[1] keep said eye uncovered and cover the other eye;
[2] placing said first plate in front of said eye;
[3] move said first plate until the user sees said object looking through said vertical slot, so that said object is centered in the field of vision that allows said vertical slot;
[d ’] repeat steps [c’.1] to [c’.3] for a second eye;
[e ’] discover both eyes; Y
[f ’] in case the user sees two vertical strips dissociatedly
corresponding to said vertical slots, adjust the position of said
first plates, to get both images to merge,
thus achieving binocular vision;
and a step to determine the vertical position, which comprises the following steps: [c ”] for a user's first eye:
[1] keep said eye uncovered and cover the other eye;
[2] placing said second plate in front of said eye, overlapping with said first plate;
[3] move said second plate until the user sees said object looking through said pinhole, so that said object is centered in the field of vision that allows said pinhole hole;
[d ”] repeat steps [c” .1] to [c ”.3] for a second eye; [e ”] discover both eyes; and [f ”] in case the user sees two points of view in a dissociated way
corresponding to said pinhole holes, adjust the position of said pinholes
second plates, to get both images to merge,
thus getting binocular vision. Thus, the vision adjustment is done in two stages, one for the horizontal position and one for the vertical position. This has the advantage that it is easier to locate the reference object, even if the grooves are narrow. This achieves greater precision together with greater ease of use. Preferably, at the stage corresponding to the horizontal position, each vertical groove is placed at the point furthest from the nasal bisector plane and converged until the reference object is located. The expert will understand that the order of the steps described above is only in a preferred way, and that the same results can be reached by starting with the stage for the vertical position followed by the stage for the horizontal position. In the latter case, the pinhole would be formed in the horizontal stage. The expert will also understand that, although vertical and horizontal grooves are discussed here, the fact that said grooves are inclined is not excluded. Indeed, the necessary condition is that in the first stage the groove facilitates the location of the reference object by the user and that in the second stage, the next groove forms a pinhole when overlapping with the groove used in the first stage. Preferably, both plates have a reduced thickness, between 0.2mm and 2mm, preferably 0.5mm, so that the passage channel of the pinhole also has a reduced length, thus minimizing diffraction effects, and allowing a greater range of angles for the possible axes of vision that pass through said hole. For similar reasons, the plates are preferably in contact with each other.
Preferably, in cases where the points [f], [f ’] or [f”] the user is not able to
get both images merged, includes the additional steps of:
- perform a measurement of the associated foria for said viewing distance;
- determine a prism necessary for said associated foria;
- repeat the measurement with the presence of said prism; Y
- design said pair of lenses for said viewing distance according also to
said prism. If the user fails to make both images converge so that binocular vision occurs, this may indicate the presence of a fixation disparity. This condition can usually be solved with the use of prisms. In particular, the prism that makes it possible to compensate for the disparity of fixation is called the associated foria. Thus, once the problem of user fixing disparity for said distance has been solved by said prism, the procedure can be repeated, so that the conditions of binocularity can be achieved at points [f], [f ’]
or [f ”]. Lenses designed in this way will also contain the prism necessary to compensate for the disparity of fixation. The expert will understand that, although for simplicity there is talk of a prism, in reality the disparity of fixation can occur both horizontally and vertically, so that the prism can have several components.
Preferably, said measurement of the associated foria is made at one of the points [e], [e '] or [e ”], or [f], [f'] or [f”], comprising the additional steps of : - placing a prism in front of one of the eyes that has a known prismatic power, said prism being overlapped with said hole;
- repeat the previous point with prisms that have different powers
binoculars until the images of both eyes merge; Y
- determine said prism necessary for said associated form as the prism
which gets the images of both eyes to merge. Thus, the elements used in the process of the invention can be used to perform the measure of associated foria, or what is equivalent, of the prism necessary to compensate for the disparity of fixation. This simplifies the process and increases user comfort. Preferably, the prism is placed on the side of said hole farthest from said eye, that is, on the outside, which has the advantage of not moving the position of the holes away from the lens use position.
Preferably, a color filter is previously interposed in the line of sight of one of said eyes, thus facilitating dissociated vision. In particular, it is convenient to force the dissociated vision when the foria is determined, since this makes it possible to determine exactly the prism that allows binocularity to be achieved. The expert will understand that in case of dissociated vision there is no talk of associated foria, since the latter is necessarily in conditions of associated vision. Thus, for some users, it is necessary to compensate for this form, for example, through the use of prisms, in order to guarantee binocular conditions. Preferably said color filter is a red filter, which has been found to easily dissociate the image.
The invention also relates to an optical measurement device aimed at facilitating the necessary measurements for said design procedure.
This purpose is achieved by means of a device for optical measurements of the type indicated at the beginning, characterized in that it also comprises: -a right screen, corresponding to the right eye of a user, comprising a first right plate and a second right plate and -a screen left, corresponding to the left eye of a user, comprising a first left plate and a second left plate, in which for each of said screens: - said first plate is mounted on said frame in a sliding direction in a horizontal direction, and has a through vertical slot; - said second plate is mounted on said frame in a sliding direction in a vertical direction, and has a horizontal through groove; each of these screens presenting:
- a first position of use in which only one of said first plate and said second plate interferes with the vision path of the eye corresponding to said screen; Y
- a second position of use in which said first plate and said second
plate interfere the vision path of the eye corresponding to said screen; wherein for said second position, said vertical groove and said horizontal groove are overlapped forming a pinhole.
Thus, the device is advantageous for carrying out the measurements of the design procedure described above. Since many of the advantages and technical effects described above are equivalent for the device described herein, its repetition will be omitted for the sake of brevity. In this way, the device allows to accurately position the location of the screens of each eye, and thus the pinhole formed by the overlap between the vertical groove and the horizontal groove. Preferably, all plates are non-transparent, which makes it easier for the user to locate the position of the reference object through the through holes. Also preferably, the corners of the grooves are beveled, more preferably with a rounded bevel, to minimize the effects of diffraction. The expert will understand that the device must allow a range of movement of the plates, so that the slots can be placed in the entire range of positions necessary for a user to see a reference object preferably from far vision to near vision. The expert will also understand that the size and shape of the device may vary depending on the type of user to whom it is intended, thus, a device aimed only at children will be smaller than one aimed only at adults. Preferably, the device is extensible in a horizontal direction so that it can adapt to the morphologies of adult and child users. Preferably, the passage between said first use position and said second use position is produced by the vertical displacement of said second plate, which minimizes the number of elements and results in a more simplified and therefore more robust device. Other preferred alternative forms comprise hinges for each of said second plates, so that the passage between said first and said second position of use comprises pivoting said second plate on said hinges. The expert will understand that said plates have a reduced thickness, preferably about 0.5mm.
Preferably, said first frame fastening means comprise grip means, configured to fasten said device to a frame of glasses by said internal side. In this way, the device can adapt to different mounts, which gives it great flexibility of use. The gripping means are arranged to hold the mount so that it is between the user and the device.
In an alternate embodiment, said first mounting means comprise pins that in mounted position extend towards said internal side, and a nasal support, configured to hold said device to the head of a user. Thus, the device itself takes the form of a spectacle frame, so that it can be used directly by the user. This also has the advantage that there is no separation between the device and the frame, so that the holes can be located in the same position where the lenses would go in the use position, thus improving accuracy. Said pins are preferably foldable and / or extensible, so that the device can be easily stored, and can also be adapted to different user morphologies.
In an alternative embodiment, the device further comprises second mounting means, which comprise pins and a nasal support, said device having a secondary mounted position in which said pins extend towards said external side, said seconds being mount fastening means configured to hold said device to the head of a user from said external side. In this way the advantages of the previous cases are combined, obtaining a dual device that can both be attached to a mount and placed directly to the user. The expert will understand that the fact of locating the second fastening means on the inner side and the first fastening means on the outer side is a solution equivalent to that described herein.
Preferably, said vertical groove has a width between 0.2mm and 5mm, preferably between 0.4mm and 0.6mm, more preferably 0.5mm. Preferably, said horizontal groove has a width between 0.2mm and 5mm, preferably between 0.4mm and 0.6mm, more preferably 0.5mm. As described above.
Preferably, said first plate is configured to allow, in said first
or said second position of use, a displacement of said vertical groove between 18mm and 40mm with respect to the nasal bisector plane. What is an advantageous range for adult users. Preferably, the device is extensible in a horizontal direction so that it can adapt to the morphologies of adult and child users.
In an advantageous embodiment, the device further comprises measuring means for determining the position of each of said slots. So that it is more comfortable and simple for the professional to obtain the vertical and horizontal position of the resulting pinhole holes.
Preferably, said measuring means are each independently one of the list consisting of: graduated ruler, nonio or reference for external measuring device. Said reference for external measuring device is preferably a hole for placing a king's foot. Preferably said means are a vernier, so that the measurement is simple, without the need for external instruments, while it is precise.
Preferably, it also comprises right holding means configured to hold at least one optical element in front of said right screen. Preferably, it also comprises left holding means configured to hold at least one optical element in front of said left screen. Preferably, each of said at least one optical element is, independently, one of the list consisting of: corrective lenses, color filters or polarizing filters. This allows the instrument itself to be used to incorporate corrective lenses or to perform associated foria measurements.
In an advantageous embodiment, said first position of use said plate between said first plate and said second plate that interferes with the vision path of the eye is said first plate. Thus, the device facilitates that the horizontal position is determined first and then the vertical position.
In another alternative embodiment, said second plate is collapsible between a position parallel to said first plate for said second use position, and a retracted retracted position for said first use position. Which has the advantage of ensuring a minimum interference of the second plate in the first position of use.
In a preferred embodiment, said second plate is movable between a position parallel to said first plate for said second use position, and a removed position displaced for said first use position, said position being also parallel to said first plate. Which simplifies the device and makes it less susceptible to mechanical failures.
Preferably, said frame has a general inverted U-shape, with an upper horizontal section, a right vertical section and a left vertical section; so that for said right screen, said first plate is movable along a right area of said horizontal section, and said second plate is movable on said right vertical section; and for said left screen, said first plate is movable along a left area of said horizontal section, and said second plate is movable on said left vertical section. Thus, the device has a simple design that allows a low manufacturing cost, while adapting to the required measurement conditions.
Preferably, each of said plates is attached to said frame and is movable along it by means of micrometric adjustment means. What confers precision in the positioning of the grooves.
Preferably, the position of said right vertical section and the position of said left vertical section are adjustable horizontally, independently of one another. Thus allowing the device to adapt to different user morphologies and the frame to which it is attached.
The invention also encompasses other detail features illustrated in the detailed description of an embodiment of the invention and in the accompanying figures.
Brief description of the drawings
The advantages and features of the invention can be seen from the following description in which, without limitation with respect to the scope of the main claim, preferred embodiments of the invention are set forth with reference to the figures.
Fig. 1 shows a simplified view of some steps of the procedure in which, by way of reference, only the frame and the screens are shown. Dashed lines represent the axes of vision.
Fig. 2 shows a simplified overhead view of a representation of the elements used in the process of the invention. As a reference, the position of use of the lenses with a dotted line is shown, as well as the axes of vision marked with a broken line.
Fig. 3 is a front view of the device according to the invention.
Fig. 4 is a rear view of the device according to the invention in which, as an example, the reference frame is shown with a broken line.
Fig. 5 is an overhead view of the device in use. For the sake of clarity, only some relevant references have been marked.
Fig. 6 is a perspective view of the device of the invention.
Fig. 7 is a perspective view of an embodiment of the device of the invention that can be carried directly by a user.
Fig. 8 is a perspective view of another embodiment of the device comprising both the support for an external mount and elements that allow it to be carried directly by a user.
Detailed description of embodiments of the invention
In figures 1 and 2, an embodiment of the design procedure of a pair of ophthalmic lenses 510, 610 is shown. In a first example, said pair of lenses 510, 610 is intended for near vision lenses, in particular for reading.
Each lens 510, 610 corresponding to an eye 500, 600 of a user. Thus, the right lens 510 corresponds to the right eye 500, and the left lens 610 corresponds to the left eye 600. In Fig. 2 the future position of use of the lenses 510, 610 is schematically represented by a dashed dotted line. The procedure comprises a measurement step comprising the following steps:
[a] Determine a viewing distance, which in the case of the example is near vision, and place a reference object 100 at a point located at said viewing distance. The object 100 is placed at the determined distance and, moreover, at a preferred angle for the user according to his preferred posture, in this case, the reading posture. To do this, in an example form, the user is asked to place himself in his usual reading posture and the reference object 100 is placed in the place where the view should be centered, for example, in the place where the user would place a Book for reading.
[b] Place a reference frame 4 to a user, configured to determine a position of use of said lenses 510, 610.
[c] For a first eye 500, 600 of the user, by way of example, for the right eye 500, although the procedure is equivalent for the left eye 600:
[1] Keeping said eye 500 uncovered and covering the other eye 600, for example, covering refers to closing eye 600 using the eyelids.
[2] Place in front of said eye 500 a screen 5 corresponding to said eye 500 provided with a through hole 520 corresponding to said eye
500. In the example shown in Figures 1 and 2, the screen 5 is an opaque card and said hole 520 is a pinhole 55 having a diameter of 0.5mm. The hole 520 shown in the figures is not to scale, so that it can be clearly seen.
[3] Move the position of said hole 520 until the user sees said object 100 looking through said hole 520, so that said object 100 is centered in the field of vision that allows said hole 520, in the case of the example , the hole 520 moves when the screen 5 in which it is provided is moved.
[d] Repeat steps [c.1] to [c.3] for a second eye 600. In the case of the example, for the left eye 600. The expert will understand that the numerical references of the steps [c.1] a [c.3] described above should be modified accordingly.
For example, for the left eye 600 the other eye corresponds to the right eye 500, the screen 6, and the through hole is 620, being a pinhole 65 having a diameter of 0.5mm.
[e] Discover both eyes 500, 600, opening the eyelids.
[f] If the user sees in a dissociated way two zones corresponding to said holes 520, 620 corresponding to said first eye 500 and said second eye 500, adjust the position of said holes 520, 620, so that both images are fused, thus getting binocular vision. In practice and by way of example, the adjustment can be of both eyes 500, 600 at the same time, or make the adjustment of each eye 500, 600 separately, which would be equivalent to repeating any of the steps [c] a [e], or a combination of both solutions. In the examples of figures 1 and 2, the moment at which the binocular vision is achieved is shown. The expert will understand that steps [c] to [f] must be performed without the user changing their position relative to the reference object 100.
In one embodiment, if the user is not able to get bothimages merge, the procedure includes the additional steps of:-Make a measurement of the associated foria for said viewing distance.-Determine a necessary prism for said associated foria.-And repeat the measurement with the presence of said prism, returning to step
[C]. In this case, the design of the pair of lenses 510, 610 for the viewing distance of is also performed according to said prism.
[g] For each hole 520, 620 corresponding to an eye 500, 600 and a lens 510, 610, make a measurement of the position of said hole 520, 620 with respect to said position of use of said lens 510, 610. In the For example, the measurement is carried out directly according to the position of each hole 520, 620 with respect to the frame 4. Alternatively, in other embodiments, the frame 4 includes reference lenses, for example lenses without graduation. In this case, a preferred embodiment is to mark on each reference lens the position of the corresponding hole 520, 620, and then measure the position of the marked point on each lens.
[h] Design each lens 510, 610 corresponding to an eye 500, 600 for said viewing distance according to said position of said hole 520, 620 corresponding to said eye 500, 600. In the example, these are lenses 510 , 610 monofocal for near vision, whose optical centers will be located according to the measured position of said holes 520, 620.
Other embodiments of the process according to the invention that share a large part of the characteristics described in the preceding paragraphs are shown below. Therefore, from now on only the differentiating elements will be described, while for the common elements reference is made to the description of the first embodiment.
In another exemplary embodiment, said viewing distance corresponds to far vision, whereby the reference object 100 is located at a point located at the optical infinity. The expert will understand that in the art said optical infinity in the case of human vision corresponds to distances of from 5m. Thus, in this example, 510, 610 monofocal lenses are designed for far vision.
In still another exemplary embodiment, the procedure is first performed for a first viewing distance, corresponding to far vision, as described above; and secondly for a second viewing distance, corresponding to near vision as described in the first example. Thus, 510, 610 bifocal lenses with two optical centers are designed: one for far vision and one for near vision, each result of a repetition of the procedure described above. In one example, lenses 510, 610 are of the type known as progressive bifocals, so that the relative position between both optical centers determines the inset and length of the aisles of each lens 510, 610.
Another embodiment of the method of the invention uses the device 1 shown in Figures 3 and 4. In this example, for each eye 500, 600, said screen 5, 6 for said eye 500, 600 comprises a first plate 51, 61, provided with a vertical groove 53, 63 through, and a second plate 52, 62, overlapped to said first plate 51, 61 and provided with a horizontal through groove 54, 64, such that said pinhole hole 55, 65 it is formed by the superposition between said vertical groove 53, 63 and said horizontal groove 54, 64. In the case of the example all the grooves have a width of 0.5mm, so that the pinhole hole 55, 65 resulting in the example has a square profile in which each side measures 0.5mm. Thus, the right screen 5 comprises a first right plate 51, provided with a right vertical slot 53. Said first right plate 51 is movable horizontally, so that the displacement of the plate 51 serves to position the slot 53 Likewise, the right screen 5 also comprises a second right plate 52, which in position of use is overlapped with the first right plate 51. The second right plate is in turn provided with a right horizontal groove 54 which when it is overlapped with the right vertical slot 53 forms a right pinhole hole 55. The device 1 allows vertical movement of the second right plate 52, used to position the right horizontal slot 54. The description is equivalent for the left screen 6.
In this exemplary embodiment, steps [c] to [f] are broken down into a stage to determine the horizontal position and a stage to determine the vertical position. In a preferred embodiment, the stage is first executed to determine the horizontal position and then the stage to determine the vertical position. In another embodiment the order is reversed. In some embodiments, the procedure begins with the user's dominant eye. For the sake of clarity, the example described below assumes that the initial eye is the right eye 500, although the expert will understand that the procedure is equivalent if starting with the left eye 600.
Thus, the step to determine the horizontal position comprises the following steps: [c ’] For a first eye 500 of the user, by way of example, the right eye 500:
[1] Keep said eye 500 uncovered and cover the other eye 600. In particular, the user closes the eyes using the eyelids.
[2] Place said first plate 51 in front of said eye 500.
[3] Move said first plate 51 until the user sees said object 100 looking through said vertical slot 53, so that said object 100 is centered in the field of vision that allows said vertical slot 53. In one embodiment Preferably, the first plate 51 moves from a remote position to a nasal bisector plane, in the direction of said plane, which favors the location of the object 100 since the vertical groove 53 moves in the same direction as the eyes when converging .
[d ’] Repeat steps [c’.1] to [c’.3] for a second eye 600, in the case of the example, for the left eye, using the elements corresponding to said left eye 600.
[e ’] Discover both eyes.
[f ’] If the user sees two vertical strips corresponding to said vertical grooves 53, 63 in a dissociated way, adjust the position of said first plates 51, 61, so that both images are fused, thus achieving binocular vision. In some embodiments, if the user is not able to get both images to be fused, the method comprises the additional foria measurement steps described above. In this case, in some exemplary embodiments, the method comprises the additional steps of: - Placing in front of one of the eyes 500, 600, by way of example, in front of the right eye 500, a prism that has a prismatic power known, said prism being overlapped with said hole 520, on the side of said hole 520 furthest from said eye 500.
- Repeat the previous point with prisms that have different prismatic powers until the images of both eyes 500, 600 merge, adjusting if necessary the position of the vertical grooves 53,
63.
- Determine said prism necessary for said associated foria as the prism that makes the images of both eyes 500, 600 merge.
On the other hand, the stage to determine the vertical position includes the following steps:
[c ”] For a user's first eye 500, by way of example, the right eye 500:
[1] Keep said 500 eye uncovered and cover the other 600 eye.
[2] Place in front of said eye 500, overlapping with said first plate 51, said second plate 52.
[3] Move said second plate 52 until the user sees said object 100 looking through said pinhole 55, so that said object 100 is centered in the field of view that allows pinhole hole 55.
[d ”] Repeat steps [c” .1] to [c ”.3] for a second eye 600, as an example, the
left eye 600.
[e ”] Discover both eyes.
[f ”] In case the user sees two vision points in a dissociated way
corresponding to said pinhole holes 55, 65, adjust the position of said second plates 52, 62, so that both images are fused, thereby achieving binocular vision. In some embodiments, if the user is not able to get both images to be fused, the method comprises the additional foria measurement steps described above.
In some embodiments in which the user presents a form, for the measurement of this, in the procedure a color filter is previously interposed in the line of sight of one of said eyes 500, 600, preferably a red filter.
In an exemplary embodiment shown in Figures 3 and 4, a device 1 for optical measurements is provided, comprising a frame 2 with a mounted position in which a user wears said device 1 in front of the eyes 500, 600 , defining an inner side facing said eyes 500, 600, and an outer side opposite said inner side, said device 1 provided with first mounting means 31, which in the case of the example comprise gripping means 31, configured to hold said device 1 to a frame 4 of glasses on the inner side of the device, that is, the one closest to the user. In Fig. 4 the front part of said mount 4 is shown in a broken line.
The device 1 of the example further comprises: - A right screen 5, corresponding to the right eye 500, 600 of a user, comprising a first right plate 51 and a second right plate 52.
- A left screen 6, corresponding to the eye 500, 600 left of a user, comprising a first left plate 61 and a second left plate 62.
All said plates 51, 52, 61, 62 being made of a non-transparent material.
Likewise, for each of said screens 5, 6: - Said first plate 51, 61 is mounted on said frame 2 slidingly in a horizontal direction, and has a vertical slot 53, 63 through. - Said second plate 52, 62 is mounted on said frame 2 so
sliding in the vertical direction, and has a horizontal groove 54, 64 through. In the case of the example, all plates 51, 52, 61, 62 have a thickness of 0.5mm, and all slots 53, 54, 63, 64 have a width of 0.5mm.
Each of said screens 5, 6 presenting:
- A first position of use in which only one of said first plate 51, 61 and said second plate 52, 62 interferes with the sight path 56, 66 of eye 500, 600 corresponding to said screen 5, 6. In the form of An exemplary embodiment shown in Figures 3 to 8 corresponds to said first plate 51, 61, whereby the horizontal position of the grooves 53, 63 is measured in the first use position.
- A second position of use in which said first plate 51, 61 and said second plate 52, 62 interfere with the vision path 56, 66 of the eye 500, 600 corresponding to said screen 5, 6.
Thus, in the example device 1 for said second position, each of the vertical grooves 53, 63 and its corresponding horizontal groove 54, 64 are overlapped forming a pinhole 55, 65.
Likewise, in the exemplary embodiment shown in Figures 3 and 4, said second plate 52, 62 is movable between a position parallel to said first plate 51, 61 for said second use position, and an offset position displaced for said first use position, said removed position being also parallel to said first plate 51, 61. Fig. 3 shows directional arrows indicating the movement of each plate.
In Figures 3 and 4, it can be seen that the device 1 shown, the frame 2 has a general inverted U-shape, with an upper horizontal section 8, a right vertical section 9 and a left vertical section 10. So that for said right screen 5, said first plate 51 is movable, by means of micrometric adjustment means 11 that hold it to the upper horizontal section 8, along a right area of said horizontal section 8. Furthermore, said second plate 52 is movable, by micrometric adjustment means 11 that hold it to the right vertical section 9, along said right vertical section 9. Similarly, for said left screen 6, said first plate 61 is movable, by means of micrometric adjustment means 11 which they hold it to the upper horizontal section 8, along a left area of said horizontal section 8. Also said second plate 62 is movable, by means of micrometric adjustment means 11 that the they hold the left vertical section 10, along said left vertical section 10. For the example device 1, each of the first plates 51, 61 is configured to allow, in the first or second position of use, a displacement of its respective vertical groove 53, 63 between 18mm and 40mm with respect to the nasal bisector plane.
In order to adjust the size of the device 1 to different users, the position of the right vertical section 9 and the position of said left vertical section 10 are adjustable horizontally, independently of one another.
The device 1 shown in Fig. 3 further comprises measuring means 57, 58, 67, 68 for determining the position of each of said slots 53, 54, 63, 64. In the case of the example, each one is shown A simplified view of a child. As an example, another possible measuring means 77, 78 is also shown in Fig. 3, which in this case comprises a reference for an external measuring device, in particular a small hole 77, 78 in which a foot of King.
Other embodiments of the device 1 according to the invention are shown below, which share much of the characteristics described in the preceding paragraphs. Therefore, from now on only the differentiating elements will be described, while for the common elements reference is made to the description of the first embodiment.
In the embodiment shown in Fig. 6, the device 1 comprises right holding means 59 configured to hold at least one optical element 7 in front of said right screen 5, as well as left holding means 69 configured to hold at least less an optical element 7 in front of said left screen 6. Each optical element of the example is, independently of one another, a corrective lens, a color filter, for example a red filter, or a polarizing filter. The expert will understand that the list described above is not exclusive and can be extended for all types of optical elements, which adds versatility to the device 1. For example, the possibility of adding red filters allows the use of the device for foria measurements.
Fig. 7 shows another embodiment of the device 1 in which the first mounting means 32, 33 comprise pins 32 which, in assembled position, extend towards the inner side, and a nasal support 33, configured to securing said device 1 to the head of a user. What is appreciated that takes the form of a frame of glasses. The pins of the example are foldable, so that they can be folded on themselves, and also extensible to be able to adapt to different morphologies of users.
The example of Fig. 8 shows yet another embodiment in which two types of mounting means are combined, one on each side of the device. Thus, the device 1, in addition to the first mounting means in the form of gripping means 31 for attaching the device 1 to a frame 4 of glasses, equivalent to Fig. 3 and Fig. 4, also comprises a few seconds. mounting means 42, 43, comprising pins 42 and a nasal support 43, said device 1 presenting a secondary mounted position in which said pins 42 extend towards said outer side, said second mounting means 42 being , 43 configured to hold said device 1 to the head of a user from said external side. The expert will understand that exchanging the position of both mounting means is a solution equivalent to that described. As an example, in Fig. 8, the pins 42 of the second mounting means are shown in the folded position.
In another embodiment, the device 1 each second plate 52, 62 of the device 1 is foldable between a position parallel to its corresponding first plate 51, 61, for the second position of use, and a retracted retracted position for the first position of use
The embodiments described so far represent non-limiting examples, so that the person skilled in the art will understand that beyond the examples shown, multiple combinations between the claimed characteristics are possible within the scope of the invention.

权利要求:
Claims (22)
[1]
1.-Design procedure of a pair of ophthalmic lenses (510, 610), each lens (510, 610) corresponding to an eye (500, 600) of a user, characterized in that it comprises a measurement step comprising the steps following:
[a] determine a viewing distance and place a reference object (100) at a point located at said viewing distance;
[b] placing a reference frame (4) to a user, configured to determine a position of use of said lenses (510, 610);
[c] for a first eye (500, 600) of the user:
[1] keep said eye (500, 600) uncovered and cover the other eye (500, 600);
[2] placing in front of said eye (500, 600) a screen (5, 6) corresponding to said eye (500, 600) provided with a through hole (520, 620) corresponding to said eye (500, 600);
[3] move the position of said hole (520, 620) until the user sees said object (100) looking through said hole (520, 620), so that said object (100) is centered in the field of vision that allows said hole (520, 620);
[d] repeat steps [c.1] to [c.3] for a second eye (500, 600);
[e] discover both eyes;
[f] in case the user sees in a dissociated way two zones corresponding to said holes (520, 620) corresponding to said first eye (500, 600) and said second eye (500, 600) adjust the position of said holes (520 , 620), to get both images to merge, thus achieving binocular vision;
[g] for each hole (520, 620) corresponding to an eye (500, 600) and a lens (510, 610), make a measurement of the position of said hole (520, 620) with respect to said position of use of said lens (510, 610); Y
[h] design each lens (510, 610) corresponding to one eye (500, 600) for said viewing distance according to said position of said hole (520, 620) corresponding to said eye (500, 600).
[2]
2. Method according to claim 1, characterized in that each of said holes (520, 620) is a pinhole (55, 65), with a diameter preferably between 0.2mm and 5mm, more preferably between 0.4mm and 0.6mm, even more preferably 0.5mm.
[3]
3. Method according to claim 2, characterized in that for each eye (500, 600), said screen (5, 6) for said eye (500, 600) comprises a first plate (51, 61), provided with a groove vertical (53, 63) through, and a second plate (52, 62), overlapped to said first plate (51, 61) and provided with a through horizontal slot (54, 64), such that said pinhole hole (55, 65) is formed by the superposition between said vertical groove (53, 63) and said horizontal groove (54, 64), and in which steps [c] to [f] are broken down in one step to determine the horizontal position that It comprises the following steps:
[c ’] for a first eye (500, 600) of the user:
[1] keep said eye (500, 600) uncovered and cover the other eye (500, 600);
[2] placing said first plate (51, 61) in front of said eye (500, 600);
[3] move said first plate (51, 61) until the user sees said object (100) looking through said vertical slot (53, 63), so that said object (100) is centered in the field of vision which allows said vertical groove (53, 63);
[d ’] repeat steps [c’.1] to [c’.3] for a second eye (500, 600);
[e ’] discover both eyes; Y
[f ’] in case the user sees two vertical strips dissociatedly
corresponding to said vertical slots (53, 63), adjust the position of
said first plates (51, 61), so that both images are
merge, thus achieving binocular vision;
and a step to determine the vertical position, which comprises the following steps: [c ”] for a first eye (500, 600) of a user:
[1] keep said eye (500, 600) uncovered and cover the other eye (500, 600);
[2] place in front of said eye (500, 600), overlapping with said first plate (51, 61), said second plate (52, 62);
[3] move said second plate (52, 62) until the user sees said object (100) looking through said pinhole (55, 65), so that said object (100) is centered in the field of vision which allows said pinhole (55, 65);
[d ”] repeat steps [c” .1] to [c ”.3] for a second eye (500, 600); [e ”] discover both eyes; and [f ”] in case the user sees two points of view in a dissociated way
corresponding to said pinhole holes (55, 65), adjust the position of said second plates (52, 62), so that both images are fused, thus achieving binocular vision.
[4]
4. Method according to any one of claims 1 to 3, characterized in that, in the points [f], [f '] or [f "] the user is not able to get both images to merge, it comprises the Additional steps of:
- perform a measurement of the associated foria for said viewing distance;-determine a necessary prism for said associated foria;-repeat the measurement with the presence of said prism; Y-design said pair of lenses (510, 610) for said viewing distance of
I also agree to that prism.
[5]
5. Method according to claim 4, characterized in that said measurement of the associated foria is carried out at one of the points [e], [e '] or [e ”], or [f], [f'] or [f ”], comprising the additional steps of:
- placing in front of one of the eyes (500, 600) a prism having a known prismatic power, said prism being overlapped with said hole (520, 620), preferably on the side of said hole (520, 620) furthest from said eye (500, 600);
- repeat the previous point with prisms that have different prismatic powers until the images of both eyes (500, 600) merge; Y
- determine said prism necessary for said associated foria as the prism that makes the images of both eyes (500, 600) merge.
[6]
6. Method according to claim 5, characterized in that a color filter is previously interposed in the line of sight of one of said eyes (500, 600), preferably a red filter.
[7]
7.-Device (1) for optical measurements, comprising a frame (2) with a mounted position in which a user wears said device (1) in front of the eyes (500, 600), defining an internal side facing said eyes (500, 600), and an outer side opposite said inner side, said device (1) provided with first mounting means (31, 32, 33), characterized in that it further comprises:
- a right screen (5), corresponding to the right eye (500, 600) of a user, comprising a first right plate (51) and a second right plate (52); Y
- a left screen (6), corresponding to a user's left eye (500, 600), comprising a first left plate (61) and a second left plate (62),
all said plates (51, 52, 61, 62) being preferably non-transparent and in which for each of said screens (5, 6):
- said first plate (51, 61) is mounted on said frame (2) slidably in the horizontal direction, and has a through vertical slot (53, 63);
- said second plate (52, 62) is mounted on said frame (2) slidably in the vertical direction, and has a horizontal slot (54, 64) through;
each of said screens (5, 6) presenting:
- a first position of use in which only one of said first plate (51, 61) and said second plate (52, 62) interferes with the vision path (56, 66) of the eye (500, 600) corresponding to said screen (5, 6); Y
- a second position of use in which said first plate (51, 61) and said second plate (52, 62) interfere with the vision path (56, 66) of the eye (500, 600) corresponding to said screen (5, 6 );
wherein for said second position, said vertical groove (53, 63) and said horizontal groove (54, 64) overlap forming a pinhole (55, 65).
[8]
8. Device (1) according to claim 7, characterized in that said first mounting means (31) comprise gripping means (31), configured to hold said device (1) to a mount (4) of some glasses on said internal side.
[9]
9. Device (1) according to claim 7, characterized in that said first mounting means (32, 33) comprise pins (32) that in mounted position extend towards said internal side, and a nasal support (33 ), configured to hold said device (1) to the head of a user.
[10]
10. Device (1) according to claim 8, characterized in that it also comprises second mounting means (42, 43), comprising pins (42) and a nasal support (43), said device (1) presenting ) a secondary mounted position in which said pins (42) extend towards said external side, said second mounting means (42, 43) being configured to hold said device (1) to the head of a user from said side external.
[11]
11. Device (1) according to any of claims 7 to 10, characterized in that said vertical groove (53, 63) has a width between 0.2mm and
[12]
12. Device (1) according to any of claims 7 to 11, characterized in that said horizontal groove (54, 64) has a width between 0.2mm and 5mm, preferably between 0.4mm and 0.6mm, more preferably 0.5mm
[13]
13. Device (1) according to any of claims 7 to 12, characterized in that said first plate (51, 61) is configured to allow, in said first or said second position of use, a displacement of said vertical slot (53 , 63) between 18mm and 40mm with respect to the nasal bisector plane.
[14]
14. Device (1) according to any of claims 7 to 13, characterized in that it further comprises measuring means (57, 58, 67, 68, 77, 78) for determining the position of each of said slots (53 , 54, 63, 64).
[15]
15. Device (1) according to claim 14, characterized in that said measuring means (57, 58, 67, 68, 77, 78) are each independently one of the list consisting of: graduated ruler, nonio or reference for external measuring device; preferably a nonio.
[16]
16. Device (1) according to any of claims 7 to 15, characterized in that it further comprises right clamping means (59) configured to hold at least one optical element (7) in front of said right screen (5).
[17]
17. Device (1) according to any of claims 7 to 16, characterized in that it further comprises left clamping means (69) configured to hold at least one optical element (7) in front of said left screen (6).
[18]
18. Device (1) according to any of claims 16 or 17, characterized in that each of said at least one optical element (7) is, independently, one of the list consisting of: corrective lenses, color filters
or polarizing filters.
[19]
19. Device (1) according to any of claims 7 to 18, characterized in that in said first position of use said plate (51, 52, 61, 62) between said first plate (51, 61) and said second plate (52, 62) that interferes with the vision path (56, 66) of the eye (500, 600) is said first plate (51, 61).
[20]
20. Device (1) according to claim 19, characterized in that said second plate (52, 62) is collapsible between a position parallel to said first plate (51, 61) for said second use position, and a collapsed withdrawn position for said first use position.
[21]
21. Device (1) according to claim 19, characterized in that said second plate (52, 62) is movable between a position parallel to said first plate (51, 61) for said second use position, and a displaced removed position for said first use position, said removed position being also parallel to said
5 first plate (51, 61).
[22]
22. Device (1) according to claim 21, characterized in that said frame
(2) has a general inverted U-shape, with an upper horizontal section (8), a right vertical section (9) and a left vertical section (10); so that for said
10 right screen (5), said first plate (51) is movable along a right area of said horizontal section (8), and said second plate (52) is movable in said right vertical section (9); and for said left screen (6), said first plate (61) is movable along a left area of said horizontal section (8), and said second plate (62) is movable on said left vertical section (10).
23. Device (1) according to claim 22, characterized in that each of said plates (51, 52, 61, 62) is attached to said frame (2) and is movable along it by means of adjustment (11) micrometers.
24. Device (1) according to any of claims 22 or 23, characterized in that the position of said right vertical section (9) and the position of said left vertical section (10) are adjustable horizontally, independently of one another.
FIG. one
FIG. 2
one
51 FIG. 3
4 31
64 6 FIG. 4 5 54
FIG. 5
one
7
FIG. 6
one

类似技术:

公开号 | 公开日 | 专利标题

US4055900A|1977-11-01|Device for making opthalmic measurements and method

KR102053389B1|2019-12-06|Device and method for determining at least one objective eye refraction parameter of a subject depending on a plurality of gaze directions

KR102026745B1|2019-09-30|Device for determining at least one sight parameter of a subject in a plurality of viewing directions

US3495897A|1970-02-17|Device for measuring the pupillary distance

ES2774195T3|2020-07-17|Ophthalmic instrument for measuring ocular refraction and visual simulation, and associated methods for measuring ocular refraction, simulation of ophthalmic elements, visual simulation and obtaining optical parameters

US4252419A|1981-02-24|Ophthalmic measuring instrument

US4208800A|1980-06-24|Method for making ophthalmic measurements

US6132045A|2000-10-17|Eyeglass frame fitting apparatus, kit and method

ES2856188T3|2021-09-27|Simultaneous Vision Simulator Miniaturized Instrument

ES2681569T3|2018-09-13|Instrument for the simulation of multifocal ophthalmic corrections

ES2632108B1|2018-06-18|DESIGN PROCEDURE FOR A PAIR OF OPHTHALTIC LENSES AND DEVICE FOR OPTICAL MEASURES

ES2718501T3|2019-07-02|Instrument for rapid measurement of the optical properties of the eye throughout the visual field

ES2631478B1|2018-07-04|Procedure, system and measuring device for the design of a pair of progressive ophthalmic lenses, manufacturing procedure and corresponding lenses.

TW202103628A|2021-02-01|Auxiliary examination device for visual focal length, and subjective pupil distance measuring device using the same for obtaining information about focusing ability of examinee's eyes

ES1275154U|2021-07-27|DEVICE FOR DETERMINING THE CENTERING OF CONTACT OR INTRAOCULAR LENSES |

BR112014033110B1|2021-10-19|DEVICE AND PROCESS FOR MEASUREMENT OF OBJECTIVE EYE REFRACTION AND AT LEAST ONE GEOMETRIC-MORPHOLOGICAL PARAMETER OF AN INDIVIDUAL

CN113208554A|2021-08-06|Optometry device with defocusing and astigmatism accurate correction functions and optometry method

CN112754424A|2021-05-07|Spectacle testing and assembling measuring frame

CN112754426A|2021-05-07|Spectacle testing and assembling measuring frame

CN112754423A|2021-05-07|Spectacle testing and assembling measuring frame

ES2526097A1|2015-01-05|Trial frame for measuring aniseiconia |

JPH07136118A|1995-05-30|Eye refractometer

Greer2003|Fitting bioptic telescopes: Determining location and mounting angle with bioptic fitting apertures

同族专利:

公开号 | 公开日

PT3605204T|2021-10-21|

LT3605204T|2021-11-10|

CN110476108A|2019-11-19|

CA3057947A1|2018-10-04|

EP3605204A2|2020-02-05|

MX2019011719A|2019-11-21|

WO2018178493A2|2018-10-04|

CN110476108B|2020-08-21|

EP3605204B1|2021-08-18|

MA49011A|2021-04-21|

WO2018178493A3|2018-11-22|

US20200103674A1|2020-04-02|

CL2019002720A1|2020-02-28|

AU2018244271A1|2019-10-24|

JP2020515918A|2020-05-28|

RU2738433C1|2020-12-14|

BR112019020198A2|2020-04-22|

ES2632108B1|2018-06-18|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US4160330A|1978-02-24|1979-07-10|American Optical Corporation|Apparatus and method for making ophthalmic measurements|

US4368958A|1979-04-23|1983-01-18|Buget Bernard J P|Arrangement for determining the points of penetration of eyeglass areas by visual axes|

US4252419A|1979-08-30|1981-02-24|Padula William V|Ophthalmic measuring instrument|

US6132045A|1996-10-10|2000-10-17|Gauvreau; Douglas K.|Eyeglass frame fitting apparatus, kit and method|

US20110273665A1|2010-05-05|2011-11-10|Norman Saffra|Eyeglass frame sizing systems and methods|

DE1833415U|1961-04-18|1961-06-22|Bruno Knobloch|MEASURING DEVICE FOR OPTICS.|

US4055900A|1975-10-02|1977-11-01|American Optical Corporation|Device for making opthalmic measurements and method|

US4190331A|1977-06-24|1980-02-26|Padula William V|Ophthalmic measuring instrument with angle measuring means|

JPS5641686Y2|1978-07-31|1981-09-30|

DE3043668C2|1980-11-19|1983-12-22|Bruno 7500 Karlsruhe Knobloch|Measuring and centering device for adjusting spectacle lenses|

DE3217940A1|1982-05-13|1983-11-24|Oculus-Optikgeräte GmbH, 6331 Dutenhofen|Measurement device for placing on spectacle frames for the determination of optical data for providing the spectacle frames with glasses|

FR2535194B1|1982-11-03|1986-04-11|Essilor Int|MEASURING DEVICE FOR MOUNTING CORRECTOR LENSES ON A GLASSES MOUNT|

JPH0235706U|1988-08-31|1990-03-08|

US5461434A|1994-06-15|1995-10-24|Mmb Optical|Optical measurement method and apparatus|

JP3240242B2|1994-09-30|2001-12-17|ホーヤ株式会社|Eye point measuring tool|

DE19929958C1|1999-06-29|2000-11-16|Kipernik Efim|Spectacles for short sight uses patterns of holes in diaphragms with or without lenses to be moved by sliding for reading or long distance viewing and according to the light in the same spectacles structure|

JP2002139713A|2000-10-31|2002-05-17|Hoya Corp|Method and device for mounting lens holders of spectacle lens|

CN2478539Y|2001-06-02|2002-02-27|孙忠义|Head-held test lenses holder|

CN100349541C|2001-11-13|2007-11-21|株式会社拓普康|Optometric device|

CN2891963Y|2006-02-27|2007-04-25|程立军|Head glasses type sight line distances tester|

US7628489B2|2006-06-09|2009-12-08|Clark Thomas H|Visual axis and alignment measurement system and method of using same|

JP4676476B2|2007-11-02|2011-04-27|愛眼株式会社|Optometry frame|

RU2511711C2|2009-01-30|2014-04-10|Хойа Корпорейшн|Method of evaluating spectacle lens, method of designing spectacle lens and method of manufacturing spectacle lens|

CN101732028A|2009-10-26|2010-06-16|金陵科技学院|Positioning method for glasses-matching cross curve of progressive lens and visual line distance measuring meter|

JP2012053236A|2010-08-31|2012-03-15|Olympus Visual Communications Corp|Convergence angle changing unit|

KR200471540Y1|2013-07-29|2014-02-28|이현주|Apparatus For Measuring The Optical Center|

FR3012952B1|2013-11-08|2015-11-06|Essilor Int|METHOD FOR DETERMINING AT LEAST ONE OPTICAL DESIGN PARAMETER OF A PROGRESSIVE OPHTHALMIC LENS|

CN103735245B|2013-12-23|2016-05-11|关伟忠|Interpupillary distance pupil height measuring instrument|

US9971172B2|2014-01-15|2018-05-15|Carl Zeiss Vision International Gmbh|Method for determining the far visual point for a spectacle lens and system therefor|WO2021110985A1|2019-12-06|2021-06-10|Essilor International|Method and system for determining a prescription for an eye of a person|

法律状态:
2018-06-18| FG2A| Definitive protection|Ref document number: 2632108 Country of ref document: ES Kind code of ref document: B1 Effective date: 20180618 |

2020-02-03| PC2A| Transfer of patent|Owner name: SPORT VISION S.L. Effective date: 20200128 |

优先权:

申请号 | 申请日 | 专利标题

ES201730494A|ES2632108B1|2017-03-30|2017-03-30|DESIGN PROCEDURE FOR A PAIR OF OPHTHALTIC LENSES AND DEVICE FOR OPTICAL MEASURES|ES201730494A| ES2632108B1|2017-03-30|2017-03-30|DESIGN PROCEDURE FOR A PAIR OF OPHTHALTIC LENSES AND DEVICE FOR OPTICAL MEASURES|

PCT/ES2018/070282| WO2018178493A2|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

US16/497,841| US20200103674A1|2017-03-30|2018-03-29|Method for Designing a Pair of Opthalmic Lenses and Device for Optical Measurements|

CN201880020611.9A| CN110476108B|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and apparatus for optical measurement|

AU2018244271A| AU2018244271A1|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

MA049011A| MA49011A|2017-03-30|2018-03-29|PROCESS FOR DESIGNING A PAIR OF OPHTHALMIC LENSES AND DEVICE FOR OPTICAL MEASUREMENTS|

RU2019129211A| RU2738433C1|2017-03-30|2018-03-29|Method for designing pair of spectacle lenses and device for optical measurements|

LTEPPCT/ES2018/070282T| LT3605204T|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

BR112019020198A| BR112019020198A2|2017-03-30|2018-03-29|method for designing a pair of ophthalmic lenses and device for optical measurements|

JP2020503369A| JP2020515918A|2017-03-30|2018-03-29|Method for designing a pair of spectacle lenses and device for optical measurement|

MX2019011719A| MX2019011719A|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements.|

CA3057947A| CA3057947A1|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

EP18736965.7A| EP3605204B1|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

PT187369657T| PT3605204T|2017-03-30|2018-03-29|Method for designing a pair of ophthalmic lenses and device for optical measurements|

CL2019002720A| CL2019002720A1|2017-03-30|2019-09-24|Design procedure for a pair of ophthalmic lenses and device for optical measurements.|

[返回顶部]