The invention relates to a radiation device for patients comprising a patient positioning device, a radiation source, and an imaging device, wherein the patient positioning device comprises at least one patient receptacle, wherein the patient positioning device is configured to perform at least a horizontal movement of the patient receptacle, wherein the imaging device comprises an imaging unit for generating an image in an imaging plane, and wherein the imaging device comprises a linear movement device for movement of the imaging unit along a vertical movement axis.
Radiation devices for patients are known that are provided with a radiation source, an imaging device, as well as a patient positioning device are known. The imaging device is usually employed in order to record immediately prior to the radiation treatment the precise position of the tissue to be irradiated in the patient. By means of the patient radiation device, the patient is initially positioned at the imaging device and subsequently at the radiation source. The imaging unit produces usually an image in an imaging plane. In order to image a larger volume, the imaging unit is moved during imaging, for example, in vertical direction. The patient radiation device is stationary during imaging in known patient radiation devices. With such a vertically movable imaging unit, imaging of seated patients can be carried out very well.
The invention has the object to provide a patient radiation device of the aforementioned kind that is of a simple configuration and can be used in various ways.
In accordance with the invention, this is achieved in that the imaging unit is rotatable about a horizontally arranged axis of rotation.
The invention thus provides that the radiation device for patients (patient radiation device) comprises an imaging unit that is rotatable about an horizontally arranged axis of rotation. In this way, a patient in a lying position can also be subjected to imaging with the imaging device when the imaging unit is arranged such that the imaging plane is vertically oriented and the patient during imaging is moved horizontally relative to the imaging unit. For the horizontal movement of the patient relative to the imaging unit, preferably the patient positioning device is utilized. A linear movement device which moves the imaging unit in horizontal direction can thus be eliminated so that a simple configuration of the system results. Due to the rotatability of the imaging unit in combination with the possibility of a horizontal movement of the patient by means of the patient positioning device, seated patients as well as patients lying down can be subjected to imaging in a simple way.
A linear movement device is to be understood herein as a movement device that is embodied to carry out exclusively a linear movement in one direction. The linear movement device comprises therefore precisely one translatory degree of freedom of movement and no rotatory degree of freedom of movement. The linear movement device is preferably a linear guide system.
Preferably, it is provided that the patient positioning device comprises a robot arm. The robot arm is advantageously movable by means of a second linear movement device along a horizontal movement axis. The robot arm is advantageously fixed to a driven carriage of the second linear movement device. Alternatively, it can also be provided that the robot arm itself can carry out a linear, horizontal movement of the patient receptacle with sufficient precision. In this case, a second linear movement device can then be eliminated.
The robot arm comprises preferably at least six axes of rotation, i.e., six axes that are independent from each other in order to be able to pivot the sections of the robot arm relative to each other. Such a six-axis robot enables free positioning and pivoting of the patient receptacle secured to the robot arm. A precise and quick positioning of the patient is possible. The patient receptacle is secured to the robot arm preferably so as to be detachable. Advantageously, the patient positioning device comprises a patient receptacle in the form of a seat and another patient receptacle in the form of a table which can be alternatively connected to the robot arm.
An advantageous arrangement is provided when the robot arm is arranged suspended from the linear movement device. The linear movement device is preferably secured at the ceiling of the room in which the patient radiation device is arranged and the robot arm is arranged with its support suspended from the linear movement device. In this way, the floor is freely accessible for other devices and a large movement range for the patient receptacle can be obtained without the utilization of the room being restricted by installations on the floor.
The imaging device and the radiation source are preferably separable from each other by a structural protective barrier. Many known imaging devices are radiation-sensitive. The radiation of the radiation source leads to wear and aging of the parts of the imaging device. By means of the spatial separation of the imaging device from the radiation source, the radiation exposure of the imaging device can be minimized. The structural protective barrier is preferably openable so that, between the imaging device on one side and the radiation source on the other side, a passage for the patient receptacle can be formed. Opening the structural protective barrier is preferably done in an automatic fashion. The movement of the patient from the room section in which the radiation source is arranged into the room section which is separated therefrom by the structural protective barrier and in which the imaging device is arranged is preferably realized by means of a combined movement of the robot arm and of the linear movement device.
A simple and pleasing configuration results when the imaging unit is of an annular shape. A patient who is in a lying position is preferably moved during imaging by the patient positioning device relative to the annular imaging unit. In case of a patient who is seated, it is preferably provided that the imaging unit during imaging is moved in vertical direction relative to the patient. At least one linear movement device is advantageously is in the form of a linear guide system. In particular, the first linear movement device and the second linear movement device are linear guide systems.
Preferably, the imaging unit comprises precisely two movement axes, i.e., the vertical movement axis and the axis of rotation. Further movement axes which enable linear movements or rotational movements of the imaging unit in space are preferably not provided. In this way, a simple configuration of the imaging unit is provided.
In order to be able to exactly position patients at the radiation source 2, a patient positioning device 3 is provided. The patient positioning device 3 comprises a linear movement device 7 which, in the embodiment, is a linear guide system driven by an electric motor, not illustrated. A robot arm 9 is secured at the linear guide system. The linear guide system comprises a single translatory degree of freedom of movement and no rotatory degree of freedom of movement. The robot arm 9 can be moved by the linear movement device 7 along a horizontally extending movement axis 8. The linear movement device 7 is preferably fixed at the ceiling of the room 32, not illustrated. Instead of the robot arm 9, a differently designed movement device, for example, an arrangement with a plurality of linear movement devices, can be provided also. In the illustration of
The robot arm 9 in the embodiment is designed as a conventional six-axis robot. The robot arm 9 comprises a support 35 which is movable by the linear movement device 7 along the movement axis 8. On the support 35, a base 10 is supported so as to be rotatable about the first axis of rotation 14. The first axis of rotation 14 is arranged vertically and perpendicular to the movement axis 8. At the base 10, a rocker 11 is supported so as to be pivotable about a second axis of rotation 15. The second axis of rotation 15 extends horizontally. At the end of the rocker 11 facing away from the base 10, an arm 12 is arranged and supported to be pivotable about a third axis of rotation 16. The third axis of rotation 16 extends parallel to the second axis of rotation 15. At the end of the arm 12 facing away from the rocker 11, a hand 13 is supported so as to be rotatable about a fourth axis of rotation 17. The fourth axis of rotation 17 extends approximately in the longitudinal direction of the arm 12. The hand 13 comprises a fifth axis of rotation 18 as well as a sixth axis of rotation 19; they are illustrated schematically in
As also shown in
The side view illustrated in
When the imaging unit 24 is moved out of the range of the patient, the patient can be moved out of the second room section 34 through the passage 26 back into the first room section 33.
Instead of a seated patient, the patient radiation device 1 can also be used for treating a patient who is in a lying position. In
After producing the image, the patient 30 is moved, as indicated schematically in
In an alternative embodiment, it can be provided that the patient positioning device 3 does not comprise a linear movement device. The horizontal movement of the patient receptacle 5, 6 in this embodiment can be carried out advantageously by the robot arm 6. For this purpose, a robot arm 6 is provided that carries out a translatory horizontal movement with sufficient precision by interpolation of rotatory movements.
The specification incorporates by reference the entire disclosure of German priority document 20 2019 001 877.8 having a filing date of Apr. 27, 2019.
While specific embodiments of the invention have been shown and described in detail to illustrate the inventive principles, it will be understood that the invention may be embodied otherwise without departing from such principles.
Number | Date | Country | Kind |
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20 2019 001 877.8 | Apr 2019 | DE | national |