RU105569U1 - ENDOSCOPE WITH INTEGRATED LED LIGHT SOURCE AND ITS POWER SUPPLY UNIT - Google Patents

Abstract

 1. An endoscope with an integrated LED light source and its power control unit, comprising an LED light source on a heat-conducting substrate, a light guide channel for transmitting light from the LED light source into the object under study, an image transmission channel for transmitting the image from the object under investigation to the outside of the recording device or eye located in the proximal part of the endoscope, while the light source LEDs are located on the heat-conducting substrate, on the heat-conducting the temperature sensor is located on the front panel, which is a microcircuit with a microcontroller having a single-wire interface, the endoscope being connected to the power supply control unit of the LED light source via a three-pin electrical connector using an electric cable, two contacts of the electrical connector are used to supply direct current to the LED light source, characterized in that at least one temperature sensor, which is a microcircuit with a microcontroller, having a single-wire in the interface is located on the case under the shell in the most heated place, the third contact of the electrical connector is connected via a single data bus to all temperature sensors installed inside the endoscope and used for sequential polling by the power supply control unit of the LED light source, the power control unit of the LED light source of the endoscope has a programmable microcontroller to automatically lower or increase the current strength of the LED light source, depending on the readings

Description

The utility model relates to the field of endoscopes. Endoscopes are widely used in various fields of endoscopy and endoscopic surgery for carrying out diagnostic and surgical procedures under visual control. Endoscopes are also widely used in technical endoscopy for the study of inaccessible places and cavities of machines and mechanisms.

There are many designs of endoscopes, common to which is the presence of a distal part that is inserted inside the test object, the proximal part remaining outside the test object, a channel for transmitting light from the light source inside the test object and a channel for transmitting the image from the test object out to the recording device or eye person. Usually, xenon, halogen, metal halide and other illuminators are used as a light source, which are a separate electronic unit, the light from which is transmitted to the endoscope using a light guide cable.

In recent years, there has been a rapid development of LED portable light sources. Their effectiveness has increased significantly, which led to the creation of miniature, but at the same time quite powerful illuminators. Known US patent No. 7229201 "Compact high-performance high-power solid-state light source using a single solid-state light emitter." It describes the device of an endoscope with a miniature LED light source, the emitting area of which is located in the proximal part of the endoscope directly on the end of the polished surface of the fiber-optic channel of the endoscope or other lighting device designed to transmit light into the human body. The high power, small size and high efficiency of the LEDs made it possible to create an endoscope that does not need an external powerful and expensive light source, as well as a light guide cable. Since LED emitters very efficiently convert electrical energy into light energy, it is powered by a current of low power. A battery powered source is used in this invention to power the LED light source. The light guide channel of the endoscope is a bundle of optical fibers of small diameter. The light guide channel may also be liquid, or made of plastic fibers, glass or plastic cylinders. The area and shape of the contact surface of the light guide channel are very close to the shape and area of the radiating surface of the LED emitter.

Between the emitting area of the LED and the contact surface of the light guide channel there may be an immersion liquid or gel to improve the conditions for the passage of light through the media interface and reduce light loss.

The disadvantage of this device is the lack of means of heat removal from the emitter. As a result of strong heating of the LED and the endoscope housing at the location of the LED during operation, they can cause burns to the operator and / or patient. If heat will not be removed from the LED, then even with a small power of the LED, its temperature will exceed the permissible one, and it will fail. In addition, the operation of the LED at an elevated temperature of the emitting area leads to a reduction in the life of the LED and premature failure of the entire endoscope.

US Patent Application 20060171693 - Endoscope with integrated light source has been published.

The endoscope described in the application also has a distal part that is inserted inside the test object, the proximal part remaining outside the test object, a channel for transmitting light from the light source into the test object, and a channel for transmitting the image from the test object out to the recording device or human eye. In the proximal part of the endoscope there is a LED light source consisting of one or many LEDs. Light from the LEDs is transmitted to the distal end through one or a plurality of light guide channels.

In this device, to solve the problem of heat removal, the LEDs are located on a heat-conducting substrate, which is connected in various ways to a radiator that radiates heat and thus cools the LEDs.

The disadvantages of this device are the lack of control over the heating of the LED itself and the endoscope housing at the location of the LED during operation, which under certain conditions can lead to overheating and failure of LEDs even with heat dissipation means. Lack of control over the temperature of the case at the location of the LEDs under certain conditions can result in burns to the user and / or patient. Such conditions may be, for example, increased ambient temperature during operation of the endoscope and (or) accidental violation of the conditions of heat exchange between the radiator and the environment during operation.

Also, as a result, it is impossible to increase the brightness of the LED light source with confidence that the temperature at critical points is under control and will not exceed the allowable under any conditions.

The purpose of the utility model is to control the heating of the endoscope with a built-in LED light source and its brightness during the operation, increasing the safety of the operator and patient, as well as the reliability and durability of the device.

The goal is achieved through the design of the endoscope. The miniature LED light source with a heat sink, located in the proximal or distal part of the endoscope, has a temperature sensor mounted on the heat sink. Temperature sensors are also fixed on the endoscope body under its shell in the most heated places and on thermal contact with the endoscope body. The most heated places are identified during testing at the stage of pilot production of the endoscope. Temperature sensors are made in the form of microcircuits with a microcontroller and have a single-wire interface. An example of such a temperature sensor is the high-precision single-wire digital thermometer DS18S20 from Maxim integrated products. The outputs of the temperature sensors on a single bus are connected to the power control unit of the LED light source. In accordance with the readings of temperature sensors, the power supply of the LED emitter is controlled.

At least one temperature sensor has a non-volatile memory in its microcircuit, in which, during the manufacture of the endoscope, information is recorded about the maximum permissible temperature of the LED light source of the endoscope and the nominal current required for its power supply. An example of such a temperature sensor is the high-precision single-wire digital thermometer DS18S20 from Maxim integrated products. At the beginning of the work, the memory is accessed by the power control unit of the LED light source of the endoscope, reads information from the memory of this temperature sensor and sets the nominal value of the supply current.

As a result, it is possible to control the illumination of the investigated object without risk to the patient, increase the safety of the operator and patient, protect the LED from overheating and failure.

Implementation of a utility model.

One of the traditional methods is to produce an endoscope with an integrated LED light source (LED or LED bar) integrated into the proximal or distal part (3 in FIG. 1), a light guide channel for transmitting light to the object under study (1 in FIG. 1), and a light guide channel for transmitting images from the studied object to the recording device (2 in figure 1). The light guide channel of the device is a bundle of optical fibers, the area and shape of the contact surface of which are very close to the shape and area of the emitting surface of the LED light source. The light guide channel may also be liquid, or made of plastic fibers, glass or plastic cylinders. LEDs are located on a heat-conducting substrate.

A temperature sensor is located on the heat-conducting substrate (4 in figure 1), which is made in the form of a microcircuit with a microcontroller and has a single-wire interface. An example of such a temperature sensor is the high-precision single-wire digital thermometer DS18S20 from Maxim integrated products.

Temperature sensors are also located inside on the walls of the body of the endoscope in the most heavily heated places during operation. The most heated places are identified during testing at the stage of pilot production of the endoscope. These temperature sensors are brought into thermal contact with the body of the endoscope, then the endoscope body is sheathed together with the sensors.

The endoscope housing houses wires for connecting temperature sensors and the power supply of the LED emitter.

An electric three-pin connector is made in the proximal part of the endoscope for connection to the power control unit of the LED light source of the endoscope using an electric cable (5 in figure 1). Two contacts are used to supply direct current to the LED light source, and the third through a single data bus is connected to all temperature sensors installed inside the endoscope, and is used for their sequential interrogation by the power control unit of the LED light source.

The power control unit for the LED light source of the endoscope has a programmable microcontroller that polls temperature sensors and records temperature data. Using the specified microcontroller, the current intensity of the LED light source is automatically reduced or increased depending on the temperature of the critical zones of the housing and the heating temperature of the LEDs in order to keep the temperature of the endoscope housing and the heat-conducting substrate of the LED light source within the range set by the operator.

At least one temperature sensor has a non-volatile memory in its microcircuit, in which, during the manufacture of the endoscope, information is recorded about the maximum permissible temperature of the LED light source of the endoscope and the nominal current required for its power supply. An example of such a temperature sensor is the high-precision single-wire digital thermometer DS18S20 from Maxim integrated products. At the beginning of work, the memory is accessed by the power control unit of the LED light source of the endoscope, reads information from the memory of this temperature sensor and sets the nominal value of the supply current, and during operation, depending on the temperature sensors and the maximum allowable temperature of the LED light source of this endoscope, the unit power control of the LED light source of the endoscope automatically lowers or increases the current strength of the LED light source to retain the body temperature of the endoscope and the heat-conducting substrate of the LED light source to the extent determined by the operator.

Description of drawings:

The figure 1 presents an endoscope with an integrated LED light source.

1. - a light guide channel for transmitting light from a light source into the investigated object,

2. - a channel for transmitting an image from a test object outward to a recording device or human eye,

3. - LED light source,

4. - temperature sensors,

5. - electrical connector,

6. - the distal part,

7. - the proximal part.

Claims (2)

1. An endoscope with an integrated LED light source and its power control unit, comprising an LED light source on a heat-conducting substrate, a light guide channel for transmitting light from the LED light source into the object under study, an image transmission channel for transmitting the image from the object under examination to the outside of the recording device or eye located in the proximal part of the endoscope, while the light source LEDs are located on the heat-conducting substrate, on the heat-conducting the temperature sensor is located on the front panel, which is a microcircuit with a microcontroller having a single-wire interface, the endoscope being connected to the power supply control unit of the LED light source via a three-pin electrical connector using an electric cable, two contacts of the electrical connector are used to supply direct current to the LED light source, characterized in that at least one temperature sensor, which is a microcircuit with a microcontroller, having a single-wire in the interface is located on the case under the shell in the most heated place, the third contact of the electrical connector is connected via a single data bus to all temperature sensors installed inside the endoscope and used for sequential polling by the power supply control unit of the LED light source, the power control unit of the LED light source of the endoscope has a programmable microcontroller to automatically lower or increase the current strength of the LED light source, depending on the readings Cove temperature to retain the body temperature of the endoscope and the heat-conducting substrate of the LED light source to the extent determined by the operator. 1. The endoscope according to claim 1, characterized in that at least one temperature sensor of the endoscope is a microcircuit with a microcontroller and non-volatile memory, in which, when manufacturing an endoscope, information is written about the maximum permissible temperature of the LED light source of the endoscope and the rated power the current necessary for its power supply, which, by means of a programmable microcontroller, at the beginning of operation, the power control unit of the LED light source of the endoscope accesses, reads the info The memory from this temperature sensor sets the nominal value of the supply current, and during operation, depending on the temperature sensors and the maximum allowable temperature of the LED light source of the endoscope, the power control unit of the LED endoscope light source automatically reduces or increases the current strength of the LED source light in order to keep the temperature of the endoscope body and the heat-conducting substrate of the LED light source to the limit x set by the operator.