RU24068U1 - FLUOROGRAPHIC INSTALLATION - Google Patents

Description

The utility model relates to medical equipment, and 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. The additional operation of securing the patient, for example, using a seat belt is laborious, which reduces throughput

fluorographic installation.

In accordance with the foregoing, the objective of this utility model is to create a fluorographic apparatus, the design of which provides a reduction in examination time, due to the possibility of through passage of patients through the installation, and to increase the safety of conducting a patient examination, by eliminating the patient’s movement.

To achieve this technical result, an X-ray source with a supply device, an X-ray receiver, a control panel, as well as an electromechanical device are additionally introduced into the fluorographic unit, which additionally includes a control unit that provides

positioning the x-ray source and the x-ray receiver to a predetermined height and connected to the corresponding inputs of the electromechanical means, wherein said electromechanical means is made in the form of two mechanically unconnected racks on which the x-ray source and the x-ray receiver are mounted, respectively, and the control panel is connected with the corresponding input of the control unit.

Preferably, the X-ray source strut is made in the form of a first tripod, consisting of at least two telescopic rails of the first tripod, on which a platform with an X-ray emitter is installed, a first elevator mounted in the first tripod with the possibility of moving the platform with an X-ray source along the indicated telescopic rails wherein the first hoist comprises a first engine with end and travel sensors.

2 In addition, the stand of the x-ray receiver is made in the form

a second tripod, consisting of at least two telescopic rails of the second tripod, on which there is a platform with an X-ray receiver, a second elevator mounted in a second tripod with the ability to move the platform with an X-ray receiver along the specified telescopic rails of the second tripod, while the second elevator contains the second engine with end and running sensors.

Advantageously, the control unit is mounted in the second tripod, and connected to the corresponding inputs of the electromechanical means through the first and second drives, respectively.

In addition, 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.

The utility model is illustrated by the example of a preferred embodiment with reference to the accompanying drawing. The drawing shows 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 1 stands for an X-ray source stand, 1 stands for a first tripod, wherein said tripod consists of a base (not shown in the drawing) of at least two telescopic guides pos. 1.2 of the first tripod, and the platform pos. 1.3, while on the site pos. 1.3 placed the x-ray source pos. 1.4 with a feed device pos. 1.5 and with aperture

3 poses 1.6 with power supply pos. 1.7. The first lift pos. 1.8 installed in the first

tripod pos. 1.1 with the ability to move the site with the source of x-ray radiation on the specified at least two telescopic guides pos. 1.2.

The first lift pos. 1.8 includes the first engine pos. 1.9 with end and travel 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 engine pos. 1.9 when moving the site in height.

At 2, the stand of the X-ray receiver is indicated, at 2.1, a second tripod consisting of a base (not indicated in the drawing), at least two telescopic guides poses. 2.2 of the second tripod, and the platform pos. 2.3, while on the specified site placed the x-ray detector pos. 2.4. The second lift 2.5 is installed in the second tripod pos.2.1 with the ability to move the platform pos.2.3. with X-ray receiver pos. 2.4 in height according to the specified at least two telescopic guides pos. 2.2.

The second lift pos. 2.5 turns on the second engine pos. 2.6 with end and running sensors (not shown in the drawing), while the end sensor limits the movement of the site pos. 2.3 with block 2.4 receiving x-ray radiation in height, and the travel sensor detects the number of revolutions of the engine pos. 2.6 when moving in height.

Under 2.7, the control unit mounted on the second tripod pos. 2.1 and, being a processor device, and providing positioning of the x-ray source pos. 1.4 and receiver

4 x-rays pos. 2.4 depending on the height of the patient in the lifts 1.8

and 2.5, respectively.

The stand 1 of the x-ray source and the stand 2 of the x-ray receiver are installed at a predetermined distance and are rigidly fixed to a horizontal surface, so that the x-ray source and the x-ray receiver are aligned along the longitudinal axis.

The device operates as follows. When the fluorographic unit is turned on, the control unit pos. 2.7 provides a control signal to turn on the first and second motors in the tripod of the X-ray source and the tripod of the X-ray receiver, 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). 2.7 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. 2.7 according to the data from the running sensor of the second lift 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.

Thus, in the claimed fluorographic installation, the positioning and movement of the x-ray source and receiver are provided separately, without moving and fixing the patient and without using mechanical interfaces between the x-ray source and receiver. The absence of any mechanical connections between the racks made it possible to reduce the area occupied by the fluorographic installation, as well as provide the patient

5

not only a free approach to the fluorographic installation from two sides, but also a through passage through it, which in due time will reduce the time required for examination.

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

Utility Model Formula

1. A fluorographic apparatus comprising an X-ray source with a power supply device, an X-ray receiver, an electromechanical device, and a control panel, characterized in that a control unit is additionally introduced therein, which provides positioning of the X-ray source and the X-ray receiver at a predetermined height and connected with the corresponding inputs of the electromechanical means, while the specified electromechanical means is made in the form of two mechanical and non-racks that are running X-ray source and X-ray radiation receiver, respectively, and the control unit is connected to the corresponding input of the control unit.

2. The fluorographic apparatus according to claim 1, characterized in that the X-ray source rack is made in the form of a first tripod, consisting of at least two telescopic rails of the first tripod, on which a platform with an X-ray emitter, a first elevator installed in the first tripod, is installed with the possibility of moving the platform with the x-ray source along the indicated telescopic rails, while the first elevator comprises a first engine with an end and running sensor ami.

3. The fluorographic apparatus according to claim 1, characterized in that the X-ray receiver rack is made in the form of a second tripod, consisting of at least two telescopic rails of the second tripod, on which a platform with an X-ray receiver, a second elevator mounted in the second tripod, is installed with the ability to move the platform with the X-ray receiver along the indicated telescopic rails

the second tripod, while the second elevator contains a second engine with end and travel sensors.

4. The fluorographic apparatus according to claim 1, characterized in that the control unit is installed in the second tripod and connected to the corresponding inputs of the electromechanical means through the first and second drives, respectively.

5. 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.

Claims (5)

1. A fluorographic apparatus comprising an X-ray source with a power supply device, an X-ray receiver, an electromechanical device, and a control panel, characterized in that a control unit is further introduced therein, which enables the X-ray source and X-ray receiver to be positioned to a predetermined height and connected with the corresponding inputs of the electromechanical means, while the specified electromechanical means is made in the form of two mechanical and unconnected racks on which the x-ray source and the x-ray receiver are mounted, respectively, 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 the X-ray source rack is made in the form of a first tripod, consisting of at least two telescopic rails of the first tripod, on which a platform with an X-ray emitter, a first elevator mounted in the first tripod, is installed with the possibility of moving the platform with the x-ray source along the indicated telescopic rails, while the first lift contains a first engine with end and running sensors kami.  3. The fluorographic apparatus according to claim 1, characterized in that the X-ray receiver rack is made in the form of a second tripod, consisting of at least two telescopic rails of the second tripod, on which a platform with an X-ray receiver, a second elevator mounted in the second tripod, is installed with the possibility of moving the platform with the X-ray receiver along the indicated telescopic rails of the second tripod, while the second elevator contains a second motor with end and running the sensors.  4. The fluorographic apparatus according to claim 1, characterized in that the control unit is installed in the second tripod and connected to the corresponding inputs of the electromechanical means through the first and second drives, respectively. 5. The fluorographic apparatus according to claim 1, characterized in that 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.