KR101210256B1 - Contact type tonometer - Google Patents

Abstract

A contact tonometer is disclosed which measures intraocular pressure by contacting a prism with an eye of a subject. The contact tonometer may include a measuring prism for deforming the measured object by pressing the measured object with a flat surface; A lever to which the measuring prism is coupled to move the measuring prism with a predetermined force; An adjusting knob for adjusting a force applied to the measuring prism and the lever; And a rotation torque adjusting device for adjusting a force applied to the measuring prism, the rotation torque adjusting device comprising: a lever rotation shaft to which the lever is connected to rotate the lever and the measuring prism with a predetermined torque; A weight weight movably mounted to the lever rotation shaft to change a rotational force of the lever rotation shaft by applying a load in a rotation direction of the lever rotation shaft; And according to the adjustment of the adjustment knob, and includes a weight position adjustment unit for moving and fixing the weight.

Description

Contact type tonometer

The present invention relates to a contact tonometer, and more particularly to a contact tonometer for measuring intraocular pressure by contacting the prism in the eye of the subject.

A contact tonometer is a device that measures the intraocular pressure (IOP) of a subject, and presses the subject's eye with an object having a flat surface to flatten the corneal part of the eye. And an ophthalmic device for calculating the intraocular pressure of the eye to be examined from the force applied to the object having the flat surface and the size of the flattened area of the eye to be examined. In the absence of external pressure, the eye is inherently spherical in shape, and the internal pressure of the eye acts to inhibit eye deformation, i.e. flattening, so when the same force is applied to the eye, The smaller the size of the flattened area of the eye, the contrary, the larger the intraocular pressure, the smaller the size of the flattened area.

1 is a view showing the overall structure of a conventional contact tonometer. As shown in FIG. 1, a conventional contact tonometer includes a measuring prism 10 having a flat surface in contact with a cornea in a measurement target, and a measurement prism 10 by applying a force to the measurement prism 10. The eye pressed by the measuring prism 10 and the lever 12 for moving the feeler arm, the adjusting prism 10 for adjusting the force applied to the measuring prism 10 and the lever 12 And a microscope mount 20 to which a slit lamp microscope for observing the state of the microscope is mounted. In the contact tonometer shown in FIG. 1, the measurer contacts the measuring prism 10 with the cornea in the object to be measured, and adjusts the adjusting knob 14 to the measuring prism 10 and the lever 12. Through the rear surface of the measuring prism 10 while increasing the losing force, the deformation of the eye to be measured, that is, the degree of flattening of the eye under examination, is observed with a slit lamp microscope. When the deformation of the measurement target reaches a predetermined level, the adjustment of the adjusting knob 14 is stopped, and the force (torque) applied to the measuring prism 10 is calculated. Since the force applied to the measuring prism 10 corresponds to the intraocular pressure of the eye under measurement, the intraocular pressure of the eye under measurement can be measured.

In the conventional contact tonometer shown in FIG. 1, a method using a cam and a method using a tension spring are used as a method of applying torque to the measuring prism 10 and the lever 12. The method using the cam is a method in which the lever 12 is rotated by the cam and the repulsive force applied to the lever 12 varies according to the position of the lever 12. The method using the tension spring is the adjustment knob 14. By turning), the tension spring increases, and the torque applied to the lever 12 is changed. However, the method using the cam has a disadvantage in that the alignment process of the parts is complicated, the force for turning the adjusting knob 14 is uneven, and the manufacturing cost is expensive, and the method using the tension spring is also a part. Because of the need for alignment and electronic components such as potential meters, there is a disadvantage that the manufacturing cost is expensive.

Accordingly, it is an object of the present invention to provide a contact tonometer with which the pressure applied to the examination can be easily adjusted. Another object of the present invention is to provide a tonometer on contact which can ensure the accuracy of the measurement while reducing the number and size of necessary parts.

In order to achieve the above object, the present invention, a measuring prism for deforming the measurement target by pressing the measurement target to a flat surface; A lever to which the measuring prism is coupled to move the measuring prism with a predetermined force; An adjusting knob for adjusting a force applied to the measuring prism and the lever; And a rotation torque adjusting device for adjusting a force applied to the measuring prism, the rotation torque adjusting device comprising: a lever rotation shaft to which the lever is connected to rotate the lever and the measuring prism with a predetermined torque; A weight weight movably mounted to the lever rotation shaft to change a rotational force of the lever rotation shaft by applying a load in a rotation direction of the lever rotation shaft; And in accordance with the adjustment of the adjustment knob, to provide a touch tonometer comprising a weight position adjustment unit for moving and fixing the weight.

The contact tonometer according to the present invention can reduce the size of the product by reducing the number and size of the necessary parts, while reducing the manufacturing cost, and can easily control the pressure applied to the examination, thereby ensuring the accuracy of intraocular pressure measurement. .

1 shows the overall structure of a conventional contact tonometer.
2 is a view showing a device for adjusting the rotational torque of the measuring prism in the contact tonometer according to an embodiment of the present invention;

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

FIG. 2 is a view illustrating a device for adjusting a rotation torque of a measuring prism in a contact tonometer according to an embodiment of the present invention, except for the rotation torque adjustment device, illustrated in FIG. 1. Conventional contact tonometer structures can be applied to the present invention. As shown in Figs. 1 and 2, the contact torometer according to the present invention includes a measuring prism 10, a lever 12, a feeler arm, an adjusting knob 14, and a rotating torque adjusting device, the rotating The torque adjusting device is for adjusting the force (torque) applied to the measuring prism 10, and includes a lever rotation shaft 30, a weight weight 40, and a weight weight position adjusting part 50.

As shown in FIG. 2, the measuring prism 10 is connected to one end of the lever 12, and the other end of the lever 12 is connected to the lever rotation shaft 30 to rotate the lever rotation shaft 30. Accordingly, the lever 12 and the measuring prism 10 rotate in a predetermined torque. A weight weight 40 for changing the rotational force of the lever rotation shaft 30 by applying a load in the rotational direction of the lever rotation shaft 30 is mounted on the lever rotation shaft 30 to be movable. According to the position, the load applied to the lever rotation shaft 30 changes, thereby changing the rotation torque of the lever rotation shaft 30. As the weight weight 40, an object having various structures and weights capable of applying a load in the rotational direction of the lever rotation shaft 30 may be used. For example, as illustrated in FIG. The weight weight 40 may have a structure fitted to the lever rotation shaft 30 to be slidably movable. The rod-shaped weight 40 changes the load applied in the rotational direction of the lever rotation shaft 30 while slidingly moving with respect to the lever rotation shaft 30. Preferably, a rail 42 extending in the longitudinal direction of the weight 40 is formed on a surface of the weight 40, and the rail 42 moves on the lever rotation shaft 30. A guide groove 32 may be formed to slide the weight 40 with respect to the lever rotation shaft 30 while preventing the weight 40 from rotating. As another method for preventing the rotation of the weight weight 40, using a rod-shaped weight weight 40 of the cross-section is a polygon, such as a square, hexagon, etc., the weight weight 40 to the lever rotation shaft 30 It may be used to form a sliding hole corresponding to the cross-sectional shape of the).

The weight weight adjustment unit 50 is a device for moving and fixing the weight weight 40 according to the adjustment of the adjustment knob 14, for example, as shown in Figure 2, the weight A rotating body that is in close contact with the weight 40 and rotates may be used as the weight weight position adjusting unit 50. Preferably, a plurality of rotor teeth 52, teeth are formed on the surface of the rotor, and the weight teeth 44 corresponding to the rotor teeth 52 are also formed on the weight 40. Thus, the rotational motion of the rotating body is transmitted to the weight tooth 44 through the rotating body tooth 52, it can be converted into a linear motion of the weight weight (40). As shown in FIG. 2, the weight position adjusting unit 50 may be rotatably fixed to the lever rotation shaft 30 or may be mounted outside the lever rotation shaft 30. Accordingly, the user may change the rotational torque of the lever 12 and the measuring prism 10 by moving the weight 40 by adjusting the weight position adjusting unit 50.

In the contact tonometer according to the present invention, the measuring prism 10, the lever 12 (feeler arm), the adjustment knob 14 and the microscope mount 20 shown in Fig. 1 are used in a conventional contact tonometer. It works the same as it does. Specifically, the measuring prism 10 deforms the measurement target by pressing the measurement target with a flat surface, and the lever 12 is coupled to the measurement prism 10 and the measurement prism 10 with a predetermined force. The control knob 14 adjusts the weight position adjusting unit 50 to adjust the force applied to the measuring prism 10 and the lever 12, and the microscope mount 20 ) Is for mounting a slit lamp microscope for observing the state of the eye pressed by the measuring prism 10 provided as necessary. The general construction of a contact tonometer according to the invention is disclosed in detail in US Pat. No. 3,070,997, the disclosure of which is all incorporated herein by reference.

Next, referring to Figs. 1 and 2, the operation of the contact tonometer according to the present invention will be described. First, the measurer contacts the measurement prism 10 with the cornea in the object to be measured, adjusts the adjustment knob 14, and gradually rotates the weight position adjusting unit 50, and the weight weight with respect to the lever rotation shaft 30. By sliding 40, the rotational torque of the lever rotation shaft 30 is increased. When the rotational torque of the lever rotation shaft 30 is increased, the force (torque) applied to the measuring prism 10 and the lever 12 increases, and the eye is deformed accordingly. The degree of deformation of the eyeball is observed through the rear surface of the measuring prism 10, and the deformation of the eyeball is at a predetermined level, that is, the diameter of the circle formed by the measurement target being pressed by the measuring prism 10 is set to a predetermined value. As early as possible, the adjustment of the adjustment knob 14 is stopped, and the force (torque) applied to the measuring prism 10 is calculated from the degree of rotation of the adjustment knob 14. Since the force applied to the measuring prism 10 corresponds to the intraocular pressure of the eye under measurement, the intraocular pressure of the eye under measurement can be calculated.

Since the contact tonometer according to the present invention directly changes the rotational torque of the lever rotation shaft 30, there is an advantage in that the manipulation applied by the measurer and the change in the rotational torque are close to the linear (linear) relationship. In the present invention, by changing the position of the weight weight 40 connected to the lever rotation shaft 30, if the rotation torque can be changed, the shape, size of the weight weight 40 and weight position adjusting unit 50 It is to be understood that the manner of movement may vary, and all such modifications are within the scope of the present invention.

Claims (5)

A measuring prism for deforming the measurement target by pressing the measurement target against a flat surface;
A lever to which the measuring prism is coupled to move the measuring prism with a predetermined force;
An adjusting knob for adjusting a force applied to the measuring prism and the lever; And
Rotational torque adjusting device for adjusting the force applied to the measuring prism,
The rotation torque adjusting device may include: a lever rotation shaft to which the lever is connected to rotate the lever and the measuring prism at a predetermined torque; A weight weight movably mounted to the lever rotation shaft to change a rotational force of the lever rotation shaft by applying a load in a rotation direction of the lever rotation shaft; And a weight position adjusting unit for moving and fixing the weight in accordance with the adjustment of the adjustment knob.
Wherein the weight is a contact weight tonometer, the weight of the rod-shaped sandwiched on the lever rotation axis. The contact tonometer of claim 1, further comprising a slit lamp microscope for observing a state of the object under measurement pressed by the measuring prism. delete According to claim 1, The surface of the weight is formed with a rail extending in the longitudinal direction of the weight, the lever rotation shaft is formed with a guide groove for moving the rail, while preventing the rotation of the weight, And a sliding weight to move the weight relative to the lever axis of rotation. According to claim 1, wherein the weight position adjusting unit is a rotating body that is in close contact with the weight, the rotating body, a plurality of rotor teeth are formed on the surface of the rotating body, the weight corresponds to the rotor teeth A weight tooth tooth is formed, the rotational movement of the rotating body is transmitted to the weight tooth through the rotating body tooth, and converted into a linear movement of the weight weight, contact tonometer.

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