RU25391U1 - FLUOROGRAPHIC INSTALLATION - Google Patents

Description

The utility model relates to medical equipment, more specifically to

X-ray diagnostic equipment.

Known fluorographic installation (see fluorograph "VERTIX UM-D manufacturer" Simens), consisting of a vertical rack, which is placed, with the ability to move "C or" P - shaped design, on opposite sides, which are fixed to the x-ray source and receiver x-ray radiation. The disadvantages of this technical solution is the complexity (bulkiness) of the positioning mechanisms, the inability to pass patients through the installation, which significantly reduces the efficiency of the fluorographic installation.

The closest analogue of the claimed utility model is a fluorographic apparatus, in which the X-ray source and X-ray receiver are rigidly fixed on the respective racks, in a horizontal plane and aligned in two axes, while the apparatus is equipped with a lifting mechanism with a stand for moving the patient into the irradiation zone, on which the patient is placed, while the specified lifting mechanism ensures the movement of the patient with the stand along the vertical axis (see. SETTING "RENEKS-fluorite producer Joint Venture" Gelpik, certificate № ROSS RU.0001.11AYU26).

The disadvantage of this technical solution is the increased risk of the required examination due to the unstable position of the patient during the examination. Additional operation of fixing the patient, for example, using

the seat belt is laborious, which reduces the throughput of the fluorographic unit.

In accordance with the foregoing, the objective of this utility model is to create a fluorographic unit, the design of which provides a reduction

examination time, due to the possibility of through passage of patients through the installation, and increasing the safety of the patient examination, due to

exceptions for patient movement, as well as increased reliability of the tripod electromechanical means.

To achieve this technical result, in a fluorographic apparatus containing an X-ray source with a power supply with a tripod electromechanical means, an X-ray receiver with a tripod electromechanical means, as well as a control panel, said tripod electromechanical means allows the X-ray source and the X-ray receiver to be moved to a predetermined height , respectively, and made in the form of two mechanically unrelated telescopes scopic rails, thus in the installation control unit is additionally introduced, which provides positioning x-ray source and receiver x-radiation to a predetermined height and connected with the corresponding inputs of the corresponding tripod electromechanical means and the control panel is connected to the corresponding input of the control unit.

In addition, each telescopic rail is equipped with a corresponding electromechanical drive with end and travel sensors.

At the same time, a platform with an X-ray source is installed on the first telescopic guide, and a platform with an X-ray receiver is installed on the second telescopic guide.

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Advantageously, said telescopic rails consist of two parts;

fixed, on which the screw is fixed, and movable, on which the nut is fixed, and adjustable rollers are installed between the movable and fixed parts.

In addition, these parts of the rails are made in the form of boxes made of aluminum and having a rectangular or square cross section.

The control unit, mainly, can be placed in the second

telescopic guide and connected to the corresponding inputs of the corresponding tripod electromechanical means through an electromechanical drive of the specified second telescopic guide.

In this case, the x-ray source is made in the form of a monoblock, including an x-ray tube in a protective metal casing and a diaphragm with a power supply.

Alternatively, in a fluorographic apparatus, said diaphragm is provided with a laser sight.

The utility model is illustrated by the example of a preferred embodiment with reference to the accompanying drawings. The drawings show the following:

FIG. 1 is a perspective view of a fluorographic apparatus according to an embodiment of a utility model.

Figure 1 shows a perspective view of a fluorographic apparatus according to the present utility model, where the first telescopic guide is made of two parts, where the fixed part of the telescopic guide is indicated by 1.1, the movable part of the telescopic guide on which the platform is installed, position 1.2 is indicated by 1.2, while on the site

3 poses 1.3 placed the x-ray source pos. 1.4 with aperture with laser

sight pos. 1.5 with power supply pos. 1.6, wherein the x-ray source is connected to the x-ray feed device pos. 1.7. The screw pos. Is fixed on the fixed part of the telescopic rail. 1.8, and on the movable part of the telescopic guide, the nut pos. 1.9, while between the movable and fixed parts of the telescopic rail mounted adjustable

rollers pos. 1.10.

The first telescopic guide pos. 1.1 and 1.2 includes the first electromechanical drive pos. 1.11 with end and running sensors (not shown in the drawing), while the end sensor limits the movement of the site pos. 1.3 with x-ray source pos. 1.4 in height, and the travel sensor detects the number of revolutions of the electromechanical drive pos. 1.11 when moving the platform 1.3 in height. In more detail, consider the process of moving the first telescopic guide pos. 1.1 and 1.2. Nut pos. 1.9 mounted on the movable part 1.2 of the telescopic rail forms a screw pair with the screw 1.8 and can move translationally along the stationary part 1.1 of the telescopic rail, but not rotate, i.e. forms a progressive pair with it. Thus, with one turn of the screw 1.8, the movable part 1.2 of the telescopic guide moves progressively by the value of the thread pitch. The rotational movement of the electromechanical drive 1.11 is transmitted to the screw 1.8 by means of a gearbox (not shown in the drawing). A travel sensor (not shown in the drawing) is installed on the gearbox of the specified electromechanical engine, with which the number of revolutions made by the screw pos. 1.8. A gear rack with end sensors (not shown in the drawing) is installed on the gearbox of the electromechanical engine 1.11, which determine the extreme lower and extreme upper position of the movable part 1.2 of the telescopic guide.

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The second telescopic guide is made similarly to the first and consists of two parts, where the fixed part of the telescopic guide is indicated by 2.1, the movable part of the telescopic guide on which the platform is installed, position 2.3, and 2.3 on the platform. 2.3 placed the x-ray receiver pos. 2.4. At the same time on a motionless

part of the telescopic rail fixed screw pos. 2.5, and on the movable part of the telescopic rail, the nut pos. 2.6, while between the movable and fixed parts of the telescopic guide mounted adjustable rollers pos. 2.7.

The second telescopic guide pos. 2.1 and 2.2 includes a second electromechanical drive pos. 2.8 with end and travel sensors (not shown in the drawing), while the end sensor limits the movement of the site pos. 2.3 with X-ray receiver pos. 2.4 in height, and the travel sensor detects the number of revolutions of the drive pos. 2.8 when moving the site in height. The mechanism for moving the second telescopic rail completely coincides with the mechanism for moving the first telescopic rail and therefore is not disclosed in the description.

Under the position 2.9 denotes a control unit installed in the second telescopic guide and which is a processor device, while the specified control unit pos. 2.9 provides positioning of the x-ray source pos. 1.4 and the X-ray receiver pos. 2.4 depending on the growth of the patient in the first and second telescopic rails, respectively.

Tripod electromechanical tool made in the form of the first telescopic guide pos. 1.1 and 1.2, and containing a source of x-ray

radiation pos. 1.4 and a tripod electromechanical tool, made in the form of a second telescopic guide pos.2.1 and 2.2, and containing an x-ray receiver pos. 2.4, installed at a predetermined distance and rigidly fixed on a horizontal surface, so that the x-ray source pos. 1.4 and X-ray receiver pos. 2.4 aligned along the longitudinal axis.

Aperture pos. 1.5 x-ray source pos. 1.4 is equipped with a laser sight (not indicated in the drawing) for the accurate installation of tripod electromechanical means during installation. The specified laser sight is also used during the operation of the fluorographic unit to control the operation of the control unit pos. 2.9.

The device operates as follows. When the fluorographic unit is turned on, the control unit pos. 2.9 gives a control signal to turn on the electromechanical drive pos. 1.11 in the first telescopic guide pos. 1.1 and 1.2 and the electromechanical drive pos. 2.8 in the second telescopic rail, pos. 2.1 and 2.2, respectively, for moving the platform pos. 1.3 with x-ray source pos. 1.4 and platforms pos. 2.3 with an X-ray receiver in a predetermined position, “the zero point from which the movement begins to count. The operator, depending on the patient’s growth and the diagnostic area, sends a signal to the control unit pos. Through the control panel (not shown in the drawing). 2.9 to move the pad pos. 2.3 with an X-ray receiver, pos. 2.4 when the required height is reached, the control unit pos. 2.9 according to the data from the travel sensor of the second electromechanical drive pos. 2.8 of the second telescopic guide pos. 2.1 and 2.2 gives a control signal to move the site pos. 1.3 with an x-ray source up to the height of the x-ray receiver pos. 2.4. The process of moving the site pos. 1.3 and platform 2.3 is carried out using the first and second

telescopic rails, while the movable and fixed parts of these telescopic rails are made in the form of boxes having a square or rectangular section, which are inserted one into the other. The use of telescopic rails of the specified profile increases the structural resistance to lateral loads and to twisting along the vertical axis. Adjustable

rollers located between the fixed and moving parts of the telescopic rail exclude the possibility of jamming during movement, even with a shifted center of gravity. In addition, the presence of rollers provides a more uniform course of the raised emitter and X-ray receiver, due to reduced vibration, while significantly reducing noise during operation of the electromechanical drive. The rigidity and stability of the fluorographic device is ensured by means of a high-precision aluminum profile, from which the movable and fixed parts of the telescopic rail are made. This design of a tripod electromechanical device allows vertical movement of the source and receiver of x-ray radiation without the use of additional nodes, providing rectilinear motion. The used aluminum profile not only serves for the equipment installed inside, but gives the design a graceful appearance, which in turn eliminates the need to install protective and decorative covers, and in turn made it possible to simplify the design of the tripod electromechanical device, significantly reduce its weight and reduce cost. .

Thus, in the claimed fluorographic installation provides positioning and movement of the source and receiver of x-ray radiation separately, without moving and fixing the patient and without the use of mechanical

7 interfaces between the source and the receiver of x-ray radiation. Lack of

any mechanical connections between the tripod electromechanical tools made it possible to reduce the area occupied by the fluorographic unit, and also provide the patient not only a free approach to the fluorographic unit from two sides, but also a through passage through it, which

time will reduce the time required for examination.

This fluorographic apparatus can be used for X-ray examination of objects.

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Utility Model Formula

1. Fluorographic installation containing an x-ray source with a power device with a tripod electromechanical means, an x-ray receiver with a tripod

electromechanical means, as well as a control panel, characterized in that the said tripod electromechanical means allows the X-ray source and X-ray receiver to be moved to a predetermined height, respectively, and are made in the form of two mechanically unconnected telescopic rails, while the control unit is additionally introduced providing positioning of the x-ray source and the x-ray receiver to a predetermined height and is connected with corresponding inputs of corresponding tripods

electromechanical means, and the control panel is connected to the corresponding input of the control unit.

2. The fluorographic apparatus according to claim 1, characterized in that each telescopic guide is equipped with an appropriate electromechanical drive with end and travel sensors.

3. The fluorographic apparatus according to claim 1, characterized in that a platform with an X-ray source is installed on the first telescopic guide, and a platform with an X-ray receiver is installed on the second telescopic guide.

4. The fluorographic apparatus according to claim 1, characterized in that each said telescopic guide consists of two parts; fixed, on which the screw is fixed, and movable, on which the nut is fixed, and between

movable and fixed parts are equipped with adjustable rollers.

5. The fluorographic apparatus according to claim 4, characterized in that said guide parts are made in the form of boxes made of aluminum and having a rectangular or square section.

6. The fluorographic apparatus according to claim 1, characterized in that the control unit is located in the second telescopic guide and is connected to

corresponding inputs of relevant tripods

electromechanical means through an electromechanical drive of the specified second telescopic guide.

7. The fluorographic apparatus according to claim 1, characterized in that the x-ray source is made in the form of a monoblock comprising an x-ray tube in a protective metal casing and a diaphragm with a power supply.

8. The fluorographic apparatus according to claim 6, characterized in that said diaphragm is equipped with a laser sight.

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Claims (8)

1. A fluorographic apparatus comprising an X-ray source with a power supply with a tripod electromechanical means, an X-ray receiver with a tripod electromechanical means, as well as a control panel, characterized in that said tripod electromechanical means move the X-ray source and the X-ray receiver to a predetermined height , respectively, and made in the form of two mechanically unconnected telescopic rails, n and in that the installation control unit is additionally introduced, which provides positioning x-ray source and receiver x-radiation to a predetermined height and connected with the corresponding inputs of the corresponding tripod electromechanical means and the control panel is connected to the corresponding input of the control unit.  2. The fluorographic apparatus according to claim 1, characterized in that each telescopic rail is equipped with a corresponding electromechanical drive with end and travel sensors.  3. The fluorographic apparatus according to claim 1, characterized in that a platform with an X-ray source is installed on the first telescopic guide, and a platform with an X-ray receiver is installed on the second telescopic guide.  4. The fluorographic apparatus according to claim 1, characterized in that each said telescopic rail consists of two parts: fixed, on which the screw is fixed, and movable, on which the nut is fixed, and adjustable rollers are installed between the movable and fixed parts.  5. The fluorographic apparatus according to claim 4, characterized in that said guide parts are made in the form of boxes made of aluminum and having a rectangular or square cross section.  6. The fluorographic apparatus according to claim 1, characterized in that the control unit is located in the second telescopic rail and connected to the corresponding inputs of the respective tripod electromechanical means through an electromechanical drive of the specified second telescopic rail.  7. The fluorographic apparatus according to claim 1, characterized in that the x-ray source is made in the form of a monoblock comprising an x-ray tube in a protective metal casing and a diaphragm with a power supply. 8. The fluorographic apparatus according to claim 7, characterized in that said diaphragm is equipped with a laser sight.