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Description  |
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FIELD OF THE INVENTION AND RELATED ART STATEMENT
This invention relates to an adaptor for measuring optically the size of an
object to be observed, the adaptor being detachably connected to the tip
of the main body of an endoscope.
Endoscopes have been employed widely in therapeutical and industrial
fields.
In order to diagnose, for example, a diseased portion developed on the
inner wall of stomach or to examine the change of such a diseased portion
with time, it is frequently necessary to measure the size of the diseased
portion or to know the distance to the diseased portion while observing
through an endoscope.
When a distance to a portion or object to be tested, such as a diseased
portion or a size from the visual field is to be estimated by a
conventional endoscope or an endoscope for measuring length, such a
distance or size has been detected from the adjusted amount of
displacement when the focus of the observing optical system has been
adjusted. Due to the inherent optical system in the endoscope, lenses
having a large depth are employed and the object to be examined has poor
change in the colors or patterns, so that precise adjustment of the focus
is difficult in such a case. Additionally, the precise measurement of
length of the object required for the diagnosis cannot be achieved.
As known, a length-measuring endoscope as disclosed in Japanese Patent
Publication No. 45911/1976 is designed so as to project a spot of light on
to the object through a projector arranged at the tip side of the insert
member so that the light is crossed at a large angle with the optical axis
of the objective lens system. A scale graduated along the direction of
displacement of the spot of light is arranged corresponding to the
distance to the object at the vicinity of the focal plane of the eyepiece
lens, thereby enabling measuring of the distance or the like from the
graduations corresponding to the position of the spot within the visual
field. However, this prior art has the disadvantage that since the means
for projecting the spot of light for measuring a length is attached
undetachably at the tip of the insert member thereby extending the length
of the hard tip portion of the endoscope, the patient is forced to put up
with severe pain during the insertion of the hard tip through the body
cavity even when length measurement is not required.
The prior art has also a disadvantage that another exclusive
length-measuring endoscope is required when the length-measuring
observation is required at a different field angles. This increases
markedly the economical burden on health care providers.
An endoscope as disclosed in Published Japanese Patent Application No.
80284/1978 has an optical system for projecting an index light together
with a normal observation optical system and illuminating optical system.
This is disadvantageous in that the endoscope has a complicated structure,
thus, increasing manufacturing costs. Further, increasing the outer
diameter of the insert member and extending the rigid tip of the insert
member results in the patient suffering severe pain during the insertion
of the insert member even when the length-measurement is not performed. It
is also disadvantageous similarly to the above-mentioned prior art in that
when the observation measuring the length at a different direction of
visual field is required, another exclusive endoscope is required which
increases very much the economical burden on health care providers and
ultimately the patients.
An endoscope as disclosed in Published Japanese Patent Application No.
80285/1978 employs a spot light having a discriminative color but has
otherwise substantially similar disadvantages to above-mentioned prior
arts.
Japanese Utility Model Publication No. 54004/1982 proposes a
length-measuring instrument wherein the light is irradiated from the side
of the a fiber lens of light converging type of changing the ion
concentration from the radial centre of a glass column to the periphery
thereof to reduce the refraction index gradually from the central side to
the surface and utilizing light issued radially as the datum line. In
addition, Published Japanese Utility Model Application No. 68110/1980
discloses an endoscope employing such a length-measuring instrument.
This prior art endoscope is provided with a normal observation optical
system and illuminating optical system at the tip side of the insert
member. The light converging lens which is irradiated with laser light
transmitted through a light converging system to the tip side on the side
thereof causes light to issue radially from the light-converging lens
which is reflected, in turn, by a conical mirror to project and display a
circle having a datum circle on the objective side.
Since this prior art is also attached undetachably at the tip of insert
member similarly to above-mentioned prior arts, it has a disadvantage that
the patient is forced to suffer from pain during the insertion into or
removal from the body cavity even when the length-measurement is not
carried out. Moreover, when the length-measurement is performed at a
different angle of field, another length-measuring endoscope is required.
Furthermore, when it is applied to a directly observing type endoscope for
observing in the forward axial direction of the insert member, the
diameter of insert member is increased to limit the site to be observed or
operated upon.
Furthermore, in published Japanese Patent Application No. 145832,1981,
there is arranged an optical fibre for projecting a target light at a
constant distance from the optical fibre for transmitting an image to
project target light from the issuing end of the optical fibre to the
object side at a constant angle with the optical axis of the optical fibre
for transmitting image to measure the distance from the tip of insert
member to the object from the position of target light image within the
visual field.
This prior art is designed to prevent any accidental injury of the object
to be observed by the tip of insert member of endoscope so that it has a
disadvantage that the size of diseased portion can substantially not be
grasped during the observation.
Moreover, when it is employed for measuring the size of diseased portion,
there occurs a problem that the required accuracy cannot be achieved
easily over a wide range of observable distances by single spot light.
OBJECTS AND SUMMARY OF THE INVENTION
It is an object of this invention to provide an optical adaptor for
measuring a length for an endoscope capable of measuring length by
attaching the adaptor to the endoscope.
It is another object of this invention to provide an optical adaptor for
measuring a length for an endoscope that is capable of measuring the
length at a different angles of field or a different direction of the
visual field.
It is still another object of this invention to provide an optical adaptor
for measuring a length for an endoscope capable of forming a datum index
suitable for measuring length.
It is still further object of this invention to provide an optical adaptor
for measuring a length for an endoscope capable for measuring the length
while lower costs.
It is still a further object of this invention to provide an adaptor which
can be inserted easily by reducing the length of the rigid tip of inset
member of the endoscope when no length-measurement is required.
This invention realizes a length-measurable endoscope capable of changing
the visual field by incorporating a projecting optical system provided
with an index and visual field-variable optical system to an optical
adaptor provided with detachably attaching means at the tip of insert
member of endoscope.
Other features and merits of this invention will become obvious by the
following description:
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1 to 6 relate to a first embodiment of this invention, wherein
FIG. 1 is a perspective view of endoscope having the first embodiment,
FIG. 2 is an enlarged longitudinal sectional view of the structure of the
tip of the insert member of the endoscope,
FIG. 3 is a schematic view showing the projecting optical system and
focusing optical system when the first embodiment is attached to the tip
of the endoscope,
FIG. 4(a) is a schematic view illustrating portionwise the projecting
optical system,
FIG. 4(b) is a sectional view taken along line C--C in FIG. 4(a),
FIG. 5 is a schematic view illustrating the image of an index observed from
the eyepiece member and
FIG. 6 is a schematic view illustrating the image of the index observed
from the eyepiece member when the projecting light is projected on an
object present farther than that in FIG. 5.
FIG. 7 is a schematic view of a second embodiment of this invention.
FIGS. 8 to 10 relate to a third embodiment of this invention, wherein
FIG. 8 is a schematic view of optical systems according to the third
embodiment,
FIG. 9 is a schematic view illustrating the image of the index observed
from the eyepiece member and
FIG. 10 is a schematic view showing the image of the index observed from
the eyepiece member when the projecting light is projected on an object
present farther from the adaptor than the object in FIG. 9.
FIGS. 11 to 14 relate to a fourth embodiment of this invention, wherein
FIG. 11 is a perspective view of the fourth embodiment,
FIG. 12(a) is an enlarged schematic top view showing portionwise of the
projecting optical system,
FIG. 12(b) is a sectional view taken along line C--C in FIG. 12(a),
FIG. 13 is a schematic view illustrating the image of the index observed
through the eyepiece member and
FIG. 14 is a schematic view illustrating the image of the index observed
through the eyepiece when the projecting light is projected on an object
present farther from the adaptor than the object in FIG. 13.
FIGS. 15 to 17 relate to a fifth embodiment of this invention, wherein
FIG. 15 is a perspective view according to the fifth embodiment of this
invention,
FIG. 16 is a schematic view of the image of the index observed through the
eyepiece member and
FIG. 17 is a schematic view of the image of the index observed through the
eyepiece member when the projecting light is projected on an object
present farther from the adaptor than the object in FIG. 16.
FIGS. 18 to 20 relate to a sixth embodiment of this invention, wherein
FIG. 18 is a perspective view of the sixth embodiment according to this
invention,
FIG. 19 is a schematic view showing the image of the index observed through
the eyepiece member and
FIG. 20 is a schematic view illustrating the image of the index observed
through the eyepiece member when the projecting light is projected on an
object present farther from the adaptor than the object of FIG. 19.
FIGS. 21 to 23 relate to a seventh embodiment of this invention, wherein
FIG. 21 is a perspective view of the seventh embodiment,
FIG. 22 is a schematic view illustrating the image of the index observed
through the eyepiece member and
FIG. 23 is a schematic view illustrating the image of the index observed
through the eyepiece member when the projecting light is projected on an
object present farther from the adaptor than the object shown in FIG. 22.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
As shown in FIG. 1, an endoscope 1 having detachably attached hereto the
first embodiment 21 of the present invention comprises an elongated and
flexible insert member 2 for inserting into a body cavity or the like, a
handle member 3 connected to the trailing end of the insert member 2 and
having a larger diameter, an eyepiece member 4 attached at the trailing
end of the handle member 3, and a flexible universal cord or light guide
cable 6 extended outwards from the side of handle member 3 and a
connecting connector at the end of handle member 3 and attachable to light
source means 5.
As shown in FIG. 1, rigid tip member 8 incorporated with observation means
and illuminating means is connected to a bend member 9 adjacent to the
trailing end of the tip member 8. Means (not shown) are connected
successively to the tip of said insert member so as to bend the bend
member 9 horizontally or vertically by turning knob 10 attached to the
handle member 3.
A light guide 11 formed from a flexible optical fibre bundle for
transmitting illuminating light is inserted through the universal cord 6
and insert member 2. The light guide 11 transmits light irradiated on one
end surface of light source means 5 from an illuminating lamp (not shown)
and projects the light from the tip surface attached fixed at tip member 8
as shown in FIG. 2 onto an object in front of the tip surface for
illuminating the object.
Tip member 8 attached fixedly the tip of the light guide 11 has a first
through-hole provided for the light guide 11, and a second through-hole
provided, for example, at a position above the first through-hole in
parallel thereto. The second through-hole is closed with a cover glass 13.
An objective optical system 14 is attached in the tip member 8 behind the
cover glass as an observation means. The leading tip of image guide 15
formed of an optical fibre bundle is attached fixedly to tip member 8 so
that the leading surface thereof is positioned at the focal plane of the
objective optical system 14 for transmitting the image focused on the
leading surface to the eyepiece member 4 so as to be observed through
eyepiece lens 16 of eyepiece member 4 as shown in FIG. 3.
The outer periphery of the tip member 8 is stepped to a smaller diameter at
the leading portion than that at the vicinity of trailing end thereof. A
stopper ring 18 provided with a protrusion ring therearound for engaging
the first embodiment of the present invention is fixedly attached to the
outer periphery of portion 17 stepped to the smaller diameter. An elastic
ring 19 functioning as a water-tight sealing member is also fixedly
attached at a more forward adjacent position. The outer periphery of
trailing end of tip member 8 is also attached fixedly with the leading end
of flexible sheath tube 20. An articulated train (not shown) is
incorporated within said sheath tube having an appropriate length and is
attached adjacent to the tip member 8 for forming the bend member 9.
In addition, a length-measuring optical adaptor 21 of the first embodiment
is attached detachably through the outer periphery of the tip member as
shown in FIG. 3.
The length-measuring adaptor 21 includes a body formed with a bore to be
fitted on the outer periphery of portion 17 having the smaller diameter at
the vicinity of trailing end of the tip member 8. The inner periphery of
trailing end side of the bore mates with stopper ring 18 and is provided
with an annular recess or groove for engaging the protrusion around the
stopper ring 18. Additionally, the inner periphery of the bore
pressure-fits with elastic ring 19 at the vicinity of said stopper ring 18
to seal the outer periphery of portion 17 with the inner periphery of the
bore to assure water-tightness.
A visual field changing optical system 22 is inserted in a first through
hole provided through the length-measuring optical adaptor at a position
confronting the objective optical system 14 incorporated within tip member
8 when the adaptor is attached to tip member 8. In addition, a projecting
optical system 23 is inserted in a second through hole provided at the
position confronting the leading tip of light guide 11. A circular index
24 having a diameter of S as shown in FIGS. 4(a) and (b) is formed around
the optical axis of projecting optical system 23 at the position outward
to the focal distance f of the projecting optical system, and preferably
at the position focusing the index at a distance of 5 to 50 mm from the
objective. The circular index is designed to be projected forwards in
concentrical cone having an apex with an angle inclined from the optical
axis at an angle of .alpha. within the conical angular illuminating range
having an apex with an angle inclined from the optical axis at an angle of
.theta. by the projecting optical system 23 as shown in FIG. 3 or FIG.
4(a).
An object in front of the adaptor within the angular focusing range defined
by a cone inclined from the optical axis at an angle of .beta. can be
focused at the leading end of image guide 15 by the focusing optical
system comprising the visual field changing optical system 22 and the
objective optical system 14. In addition, the optical axes of the visual
field-changing optical system 22 and the projecting optical system 23 are
designed to be in parallel to each other and apart by a constant distance
l with respect to each other.
Since the focusing angular range .beta. is set to be equal to the
projecting angle .alpha. of index 24, the distance defined by the
uppermost point of visual field of circular focusing range or the
observation range and the uppermost point of arc of projected index 24 is
kept at a constant value irrespective of the object viewed as shown by
line A--A' spaced from the leading end of length-measuring optical adaptor
by a distance D.sub.1 or as shown by line B--B' spaced from the adaptor by
a distance D.sub.2 as shown in FIG. 3. In other words, if the distance
between the heights of light of index 24 on the first lens plane of the
projecting optical system 23 is assumed to be L as shown in FIG. 3, then
the value L is a constant irrespective of the distance to the object being
viewed.
In the first embodiment, datum length displaying means are formed by
providing a datum length of L on the side of the object desired to be
measured for length. (In addition, the surface of object for forming the
image of circular index by means of projecting optical system 23 is shown
as being inclined relative to a plane perpendicular to the drawing for
convenience in FIG. 3. In other embodiments, the image of index may be
provided at an incline.) Hence, when the object on line A--A' or B--B' is
observed through eyepiece member 4 as shown in FIG. 3, a portion of the
image of the index as represented by numeral 24" is focused, the image of
the index projected on the surface of the object as represented by numeral
24' is observed as shown by broken line in FIGS. 5 or 6. The length from
the uppermost point of visual field and the uppermost point of the arc of
the image of the index 24" corresponds to the datum length L.
Accordingly, a size or length of an object within the observing visual
field can be estimated easily from the constant and correct length
displayed within the visual field or estimated more accurately by
utilizing photography or the like.
In addition, distance D to the object can be calculated from an equation:
R/(D-f)=S/2f
or
D=f(2R+S)/S
wherein the radius of index 24' projected on the object surface at a
distance of D is assumed to be R. (S is the actual diameter of the
circular index 24 and f is the focal distance of the projecting optical
system 23). When R>>S, then
D=2fR/S
and R can be calculated from the datum length L.
The operation of first embodiment having a structure as stated hereinabove
is as follows:
When the bore of the length-measuring optical adaptor 21 according to the
first embodiment is fitted onto portion 17 having a smaller diameter of
tip member 8 of endoscope 1 and pressed, the protruded ring of stopper
member 18 is received in the ring groove provided around the inner
periphery of the bore of the adaptor 21 to engage the adaptor with the tip
member. The length-measuring adaptor 21 engaged with the tip member is
inserted, for example, from the oral cavity through the body cavity to the
position confronting the object to be examined and the object is observed
at a distance suitable for the observation. In such a case, the
illuminating light from the illuminating lamp (not shown) in light source
means 5 is transmitted through light guide 11 and irradiated from the
leading end of light guide through projecting optical system 23 within the
range of illuminating angle .theta.. Index 24 is projected through
projecting optical system 23 on the surface of object in a circular form
at an angle of .alpha..
Since angle .beta. of the field of the focusing optical system is equal to
the angle .alpha., a portion of the image 24" for the projected index 24'
is observed together with the illumination by the illuminating optical
system as shown in FIGS. 5 or 6. Since the length from the uppermost point
of visual field to the uppermost point of the image of the index 24"
projected within the visual field corresponds to constant datum length L,
the length of diseased portion or the like within the observing visual
field can be estimated from the datum length L substantially irrespective
of distance D to the object and can be more accurately determined from
photographs taken through the endoscope.
As set forth hereinbefore, distance D to the objective can be calculated
from the equation of
D=f(2R+S)/S.
Moreover, according to this first embodiment, the projected image forms an
arc, so that if a portion is not discriminated easily, it can be
calculated from other distinct portions by extrapolation. The distance and
size of the object viewed can be always estimated to help very much in the
diagnosis and observation.
Still more, when the length is not required to be measured, the endoscope
can be employed in a similar manner to a conventional endoscope by
detaching the length-measuring optical adaptor 21. Since the length of
rigid tip portion can be reduced to that of tip member 8, the pain
experienced by a patient can be mitigated during the insertion of tip
member through the body cavity of patient. The illumination can be
increased by elimination of the loss in the intensity of illuminating
light previously caused by index 24. Still further, when the endoscope is
employed by detaching the length-measuring optical adaptor, it is
preferred to attach a ring cover around the outer periphery of portion 17
having reduced diameter so that stopper member is 18 kept out of the way
during the insertion and removal of the tip member of the endoscope.
FIG. 7 illustrates the second embodiment of this invention.
In length-measuring optical adaptor 31 according to the second embodiment,
two through holes are provided so that the trailing ends thereof confront
respectively the leading ends of the objective optical system 14 and the
light guide 11. The holes are bent through a right angle midway to open
through the side of the adaptor. The through-holes are provided
respectively with a visual field-changing optical system 32 and a
projecting optical system 33, each attached optically with prisms.
Circular index 24 is provided at the rear side of the projecting optical
system 33. This second embodiment is only different from the first
embodiment of a directly forward viewing type relative to the axial
direction of tip member 8 in that it is a side-viewing type to the
direction perpendicular to the axial direction of tip member 8 so that the
same members corresponding to those of the first embodiment are
represented by the same numerals. In addition, the function thereof is
substantially equal to that of the first embodiment. Moreover, the
distance between the both optical axes bent perpendicular to the side is
represented by "l" and the distance between the height of angle of visual
field and height of index is represented by datum length "L".
If the adaptors of first and second embodiments are provided, the directly
forward and sideward visual fields can be observed under the
length-measuring condition by employing a single endoscope. In addition,
an adaptor having a different angle of field can be provided according to
the first or second embodiment. Since these adaptors according to the
first and second embodiments can be attached detachably to the same
endoscope, such attachments can be realized with low costs.
FIG. 8 illustrates the third embodiment of this invention. In the
length-measuring optical adaptor 41 according to the third embodiment,
linear index 42 is provided in lieu of the provision of circular index 24
as in the first embodiment so that the linear index 42 crosses the optical
axis of projecting optical system 23 and is perpendicular to the plane
including both optical axes of visual field-changing optical system 22 and
projecting optical system 23. In addition, a datum index 43 is provided so
that it passes the centre of visual field in parallel to projected index
42' of the linear index 42.
In such a structure, the projected index 42' is projected always so as to
be parallel to the optical axis of visual field-changing optical system 22
or objective optical system 14 and to be aligned with the extended optical
axis of projecting optical system 23. The distance between projected index
42' and the optical axis of visual angle-changing optical system 22 is
kept always at a constant length L.
Consequently, when indexes 42', 42' projected on the surfaces of an object
spaced from the leading end of adaptor by a distance D.sub.1, D.sub.2 are
observed through eyepiece member 4, projected images of linear indexes
42", 42" are observed in parallel to the line of image 43' of the datum
index 43 as shown in FIGS. 9 and 10. The distances between the two
parallel lines are equal to datum length L in both cases. The effect
thereof is substantially equal to that according to the first embodiment.
In addition, according to the third embodiment, the index is positioned at
a constant point when an optical adaptor having different visual angle is
manufactured, so that a common projecting optical system 22 can be
utilizable to reduce the manufacturing costs.
Moreover, since datum length L is defined at the centre of visual field, it
is easily seen and facilitates the measurement of length.
Still further, when the main body of endoscope is connected with a
television camera, datum index 43 may be attached not to the endoscope but
to the monitor display. By the way, the datum index 43 is not always
necessary.
FIG. 11 illustrates the fourth embodiment of this invention.
Length-measuring optical adaptor 51 of the fourth embodiment is provided
with two projecting optical systems. 52, 52.
Two light guides 11, 11 are arranged spaced apart at a central distance of
L to each other, for example on the lower portion of the objective optical
system of endoscope 1' to form an illuminating means as shown in FIG. 12.
Through-holes are provided through the length-measuring optical adaptor 51
is confronting relation with the light guides 11, 11 and projecting
optical systems 52, 52 are incorporated therein. As shown in FIGS. 11 and
12, linear indexes 53, 53 are provided so as to cross perpendicularly to a
straight line connecting the optical axes of projecting optical systems
52, 52 and are parallel to each other. The distance between two indexes
53, 53 is kept always at a constant length of L (for example, 3 mm) and
the distance of projected indexes 53', 53' are also kept at the length L.
Consequently, when the image projected at line A--A' or lines B--B' as
shown in FIG. 11 is observed through the eyepiece member, it is observed
as shown in FIG. 13 or 14. The distance between the images of indexes 53",
53" is proved to be equal to the constant length L. In addition, the
portion confronting the objective optical system of length-measuring
adaptor 51 is provided with visual field changing optical system 54.
Since the fourth embodiment is provided with two illuminating optical
systems, the illuminating light intensity is higher than that in a single
illuminating optical system. Other effects are similar to that of the
third embodiment.
FIG. 15 illustrates the fifth embodiment of this invention.
Length-measuring optical adaptor 61 according to the fifth embodiment is
applied to an endoscope 1" provided with four illuminating optical
systems.
As shown in FIG. 15, visual field changing optical system 62 is provided at
the centre and four projecting optical systems, 63, 63; 64, 64 are
provided so as to be spaced apart from the visual field changing optical
system 62 by an equal central distance of L/2 and to be symmetrical with
respect to the optical axis of the visual field changing optical system
62. Two pairs of linear indexes 65, 65; 66, 66 are provided for each pair
of projecting optical systems 63, 63; 64, 64 each in parallel. Hence,
images of indexes 65", 65"; 66", 66" are observed within the visual field
observed through the eyepiece member when the indexes are provided to a
position relatively nearer from the adaptor as shown in FIG. 16 and images
of indexes 65", 65"; 66", 66", are observed when the indexes are projected
to a position relatively farther from the adaptor as shown in FIG. 17. The
distances between a pair of images of the indexes 65", 65" and between
another pair of images of the indexes 66", 66" are equal to a constant
length L.
Other structure and functioning of the fifth embodiment are similar to
those of first and second embodiments.
Since the datum length L is indicated concurrently to the longitudinal and
transverse directions in the fifth embodiment, the measurement of length
is performed more easily. In addition since there are provided four
illuminating optical systems, the intensity of illuminating light is
increased much more.
FIG. 18 illustrates the sixth embodiment of this invention.
Length-measuring optical adaptor 71 according to said sixth embodiment is
provided with spot index 72, 72 to the projecting optical systems 52, 52
in lieu of linear indexes 53, 53 for the length-measuring optical adaptor
51 as shown in FIG. 11. A datum index 43 is provided to eyepiece member 4
as shown in FIG. 8. This datum index 43 is positioned so as to pass the
centre of visual field and in parallel to the plane including the optical
axes of projecting optical systems 52, 52 spaced apart by a distance of L
with respect to each other and so that the distance from the datum index
43 to the plane is equal to a constant datun length of L.sub.1.
Accordingly, within the visual field observed through the eyepiece member
when the indexes are projected on a plane nearer or further from the
leading end of adaptor, images of indexes 72", 72" are developed. The
distance between the two images corresponds to datum length L and the
distance to the image of datum index 43' corresponds to datum length
L.sub.1 as shown in FIGS. 19 and 20, respectively.
According to the sixth embodiment, datum lengths L.sub.1 and L are
displayed concurrently to the longitudinal and transverse directions and
since there is provided no limitation in the rotational directions of
indexes 72, 72 attached to projecting optical systems 52, 52 or no
requirement for arranging two indexes 72, 72 precisely in parallel to each
other, such conditions are preferable in the assembly of adaptor.
Furthermore, it is possible to set L-L.sub.1 by setting the positional
relation of projecting optical systems 52, 52 and visual field-changing
optical system 54.
FIG. 21 illustrates the seventh embodiment of this invention.
Length-measuring optical adaptor 81 according to the seventh embodiment is
provided with four spot indexes 82, 82, 82, 82 on the optical axes of
projecting optical systems 63, 63; 64, 64 in lieu of linear indexes 65,
65; 66, 66 on projecting optical systems 63, 63; 64, 64 shown in FIG. 15.
The distances between the two sets of confronted indexes 82, 82 are kept
in a constant datum length L. Accordingly, when the images projected on a
plane nearer or further from the leading end of adaptor are observed, the
images of indexes 82", 82", 82", 82" are observed respectively as shown in
FIGS. 22 and 23. The distances between two sets of confronted images 82",
82" are equal to datum length L.
The seventh embodiment has an effect substantially similar to that of the
sixth embodiment. In addition, four illuminating optical systems are
employed so as to increase the intensity of illuminating light.
In addition, endoscope 1, 1', 1" applied with an adaptor according to any
embodiment is not limited to a flexible type employing fibre bundle(s) for
forming the image guide(s) 15 as image transmitting means but may be a
rigid type endoscope employing optical relay system(s). It may be flexible
or rigid type employing solid pick-up element(s) such as charge-coupled
device, BBD or the like.
Moreover in each of above-mentioned embodiments, visual field-changing
optical system 22, 32, 54, 62 includes that changing the angle of visual
field of objective optical system 14 only in the main body of endoscope
and that changing the direction of visual field. The present invention
includes an adaptor designed to measure the length by projecting a
length-measuring index at the same angle of field without changing the
angle of the field.
Moreover, as length measuring indexes, there have been disclosed linear,
circular and spot indexes, but the index may be formed otherwise.
Moreover, the index may be provided on a lens member of the projecting
optical system, glass plate or glass rod and displayed with a
discriminating color such as green or blue in the observation of body
cavity. When a plural number of indexes are projected on a plane, they can
be displayed by different colors.
Still further, in length-measuring optical adaptors 21, 31, . . . , 81
disclosed, the body of the length-measuring optical adaptor may not be
formed integrally but may be formed in two pieces so that, for example,
the part forming the index may be attached detachably to the main body of
adaptor so that when the part is detached, the adaptor is used as an
optical adaptor having no index-projection means but the angle of field or
direction of visual field may be changed and when the part is attached,
the adaptor is used as a length-measuring optical adaptor.
Still further, when the adaptor according to this invention is not attached
and the endoscope has stepped tip member 8 having possibility of injuring
the inner wall of body cavity during the insertion or the like, a cover
member of substantially ring form may be fitted to eliminate the stepped
portion.
Still further, although the above-mentioned embodiments do not have an
instrumental channel, for an insert member equipped with an instrumental
channel, an additional through-hole connected to the channel may be
provided.
Still further, this invention, includes any combination of above-mentioned
embodiments. For example, the adaptors according to the first and second
embodiments can be combined to be used for the same endoscope 1.
Still further, the objective optical system and single or plurality of
illuminating optical system(s) are not limited to those mentioned
hereinabove.
As set further hereinbefore, this invention provides an optical adaptor for
measuring length of an object viewed by incorporating an optical adaptor
capable to be attached detachably to the insert member of an endoscope
with an index or indexes, thereby displaying a datum length by projecting
the index(s) on the surface of object to be observed so as to change the
visual direction or the angle of field only be exchanging another optical
adaptor for measuring the length without degrading the measuring function
to extend the applications of optical adaptor economically.
Moreover, when such function for measuring the length is not required, the
endoscope can be employed as an ordinary endoscope without losing the
light intensity by detaching the optical adaptor economically.
Moreover, when such function for measuring the length is not required, the
endoscope can be employed as an ordinary endoscope without losing the
light intensity by detaching the optical adaptor.
Still further, it is apparent that different embodiments based on this
invention can be thought of within a wide range without departing from the
spirit and scope of this invention. Hence this invention is not restricted
to any particular embodiments except the limitation as claimed by the
attached claims.
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