Patent Grant
11246544
This application claims priority to Chinese Patent Application No. 201810206264.0 filed on Mar. 13, 2018, the entire content of which is incorporated herein by reference.
The present relates to scanning tables and medical imaging equipment including the scanning tables in the medical imaging field.
In the diagnosis process of some diseases in patients, a variety of different imaging technologies may be used to scan and image the patients, so as to assist the diagnosis. Those imaging technologies may include MRI (Magnetic Resonance Imaging), CT (Computed Tomography), PET (Positron Emission Tomography), etc., and relevant medical imaging equipment usually includes a scanning table to support the patient.
NEUSOFT MEDICAL SYSTEMS CO., LTD. (NMS), founded in 1998 with its world headquarters in China, is a leading supplier of medical equipment, medical IT solutions, and healthcare services. NMS supplies medical equipment with a wide portfolio, including CT, Magnetic Resonance Imaging (MRI), digital X-ray machine, ultrasound, Positron Emission Tomography (PET), Linear Accelerator (LINAC), and biochemistry analyser. Currently, NMS' products are exported to over 60 countries and regions around the globe, serving more than 5,000 renowned customers. NMS's latest successful developments, such as 128 Multi-Slice CT Scanner System, Superconducting MRI, LINAC, and PET products, have led China to become a global high-end medical equipment producer. As an integrated supplier with extensive experience in long medical equipment, NMS has been committed to the study of avoiding secondary potential harm caused by excessive X-ray irradiation to the subject during the CT scanning process.
The present disclosure provides scanning tables and medical imaging devices or systems including such scanning tables, which can implement long distance back and forth movement.
One aspect of the present disclosure features scanning table including: an upper pallet configured to support a subject; a lower pallet; a support device configured to support the upper pallet and the lower pallet; a driving device configured to drive the upper pallet and the lower pallet to move in a front-back direction; an opening belt configured to drive the lower pallet to move in the front-back direction relative to the support device; and an endless belt configured to drive the upper pallet to move in the front-back direction relative to the lower pallet. The opening belt is fixedly coupled with the lower pallet, and the endless belt is fixedly coupled with the upper pallet. A front end of the opening belt is provided with a first driving wheel coupled to the driving device and an axis of the first driving wheel is in a left-right direction of the scanning table, and the lower pallet is driven by the first driving wheel to move in the front-back direction relative to the support device. The endless belt is sleeved on the lower pallet and configured to, when the lower pallet moves in the front-back direction relative to the support device, move synchronously with the lower pallet to drive the upper pallet to move in the same direction back and forth relative to the lower pallet.
In some implementations, the driving device includes: a reversing device; a power component disposed at a back end of the scanning table; and a transmission shaft disposed along the front-back direction, an axis of the transmission shaft being along the front-back direction. A back end of the transmission shaft is coupled to the power component, and a front end of the transmission shaft is coupled to the reversing device, and a power is transmitted to the first driving wheel by the reversing device.
In some examples, the reversing device includes: a second driving wheel and a third driving wheel cooperated with the second driving wheel. An axis of the second driving wheel is in the left-right direction of the scanning table and is coupled circumferentially with the first driving wheel, and an axis of the third driving wheel is in the front-back direction and is coupled to the front end of the transmission shaft. Both of the second driving wheel and the third driving wheel can be spiral bevel gears or straight tooth bevel gears.
In some examples, the reversing device includes a right angle reducer.
In some implementations, the scanning table further includes: a front connector fixedly coupled with the front end of the opening belt and a back connector fixedly coupled with a back end of the opening belt. The front connector is ahead of the first driving wheel along the front-back direction. A front end of the lower pallet can be fixedly coupled with the front connector, and a back end of the lower pallet can be fixedly coupled with the back connector.
In some examples, the opening belt includes a front opening belt located in front of the first driving wheel and a back opening belt located behind the first driving wheel, and the front opening belt and the back opening belt are disposed in a same plane above the first driving wheel. The front connector can be fixedly coupled to a front end of the front opening belt, and the back connector can be fixedly coupled to a back end of the back opening belt.
The scanning table can further include: a first transmission wheel above the first driving wheel, the first transmission wheel being located below the opening belt and configured to guide the front opening belt to extend upward; and a second transmission wheel above the first driving wheel, the second transmission wheel being located below the opening belt and configured to guide the back opening belt to extend upward. The first driving wheel can be located between the first transmission wheel and the second transmission wheel and above a portion of the opening belt that is between the front opening belt and the back opening belt.
The endless belt can be coupled with a first connector fixed on the support device. A lower part of the endless belt can be fixedly coupled to the support device by the first connector, and an upper part of the endless belt can be fixedly coupled to the upper pallet by a second connector. The first connector can be disposed at a front end of the lower part of the endless belt, and the second connector can be disposed at a back end of the upper part of the endless belt.
In some implementations, the scanning table further includes: a third transmission wheel hinged at a front end of the lower pallet; and a fourth transmission wheel hinged at a back end of the lower pallet. A hinge shaft of the third transmission wheel and a hinge shaft of the fourth transmission wheel can be in the left-right direction of the scanning table, and the endless belt can be sleeved on the third transmission wheel and the fourth transmission wheel.
The opening belt can include a synchronous belt or a chain, and the first driving wheel can include a synchronous pulley or a chain wheel. The endless belt can include a synchronous belt or a chain, and both of the third transmission wheel and the fourth transmission wheel can be synchronous pulleys or chain wheels.
A length of the opening belt can be substantially half of a length of the endless belt.
Another aspect of the present disclosure features a medical imaging system. The medical imaging system includes an imaging device configured to scan a region of interest of a subject and a scanning table configured to support the subject. The scanning table can include one or more features of the scanning table as described above.
The details of one or more examples of the subject matter described in the present disclosure are set forth in the accompanying drawings and description below. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims. Features of the present disclosure are illustrated by way of example and not limited in the following figures, in which like numerals indicate like elements.
The present disclosure will be specifically described below in conjunction with the accompanying drawings, so that those skilled in the art may accurately understand the technical solutions of the present disclosure.
Up, down, left and right directions described herein are based on a normal use state of medical imaging equipment. The term “medical imaging equipment” herein can be used interchangeably with “medical image device” or “medical image system”. During the process of using the medical imaging equipment, a direction perpendicular to a ground is an up and down direction, a direction of vertically pointing to the ground is downward, and a direction vertically away from the ground is upward. A length direction of the scanning table is a front-back direction. In the length direction of the scanning table, a direction towards an imaging device of the medical imaging equipment is forward, and a direction away from the imaging device is backward. The scanning table may be sent into the imaging device from back to front and retracted to a support device from front to back. In a plane parallel to the scanning table, a direction perpendicular to the front-back direction is a left-right direction, that is, a width direction of the scanning table is the left-right direction. When a subject lies on the scanning table, the direction of the left hand of the subject is left, and the direction of the right hand of the subject is right.
The terms first, second, third and so on used herein are used to distinguish two or more components that are identical or similar in structure, or two or more structures that are identical or similar, and do not represent a particular limitation of the order.
The medical imaging equipment includes a scanning table for supporting a subject. The medical imaging equipment can include, but not limited to, MRI equipment, CT imaging equipment, PET imaging equipment, and X-ray imaging equipment. MRI equipment is exemplified below to describe a scanning table of the medical imaging equipment.
MRI equipment is widely used in medical clinical and scientific research, and includes a magnet, a gradient coil, a radio frequency (RF) transmitting coil, a RF receiving coil, and a scanning table for supporting a subject. The scanning table is configured to move the subject to a main magnetic field and a gradient field generated by the magnet and the gradient coil. The RF transmitting coil is configured to excite the subject to generate magnetic resonance signals. The RF receiving coil is configured to receive the generated magnetic resonance signals and sends them to a computer. The computer is configured to reconstruct a magnetic resonance image based on the generated magnetic resonance signals. If a whole body scan of the subject is to be performed in the MRI equipment based on one-time positioning (one posture lying on the scanning table), a pallet of the scanning table is to have a moving distance of 2,800 mm or even 3,000 mm.
Limited by the installation space of the MRI equipment and the structure of the scanning table, in an example, the scanning table includes a double-layer pallet structure and a horizontal driving device including a power source. The double-layer pallet structure includes an upper pallet for supporting the subject and a lower pallet. The lower pallet is driven by the power source to move horizontally in the front-back direction, so as to form a first-stage drive. The upper pallet is driven by the lower pallet to move horizontally in the same direction as the lower pallet, so as to form a second-stage drive, thereby implementing long distance back and forth movement of the upper pallet of the scanning table.
A scanning table of the medical imaging equipment shown in
As shown in
The imaging device may be a magnet 400, and may be an imaging device used in other medical fields such as CT or PET.
As shown in
As shown in
The scanning table may include components for performing back and forth movement except the support device 402 and the subject 403. The components can include one or more of the driving device 401, the upper pallet 410, the lower pallet 414, the opening belt 416, the endless belt 412, and the like.
As shown in
In some examples, the endless belt 412 is sleeved on the lower pallet 414. The endless belt 412 may be coupled with a first connector 428 fixedly installed on the support device 402. As the lower pallet 414 is driven to move back and forth relative to the support device 402, the endless belt 412 is driven to move back and forth along with the lower pallet 414 since the endless belt 412 is sleeved on the lower pallet 414. A portion of the endless belt 412 is fixedly coupled to the support device 402 by the first connector 428, and thus, when the lower pallet 414 is driven to move back and forth relative to the support device 402, the endless belt 412 is driven to rotate in the rotating direction of the endless belt 412 relative to the lower pallet 414. In this process, the portion of the endless belt 412 coupled with the first connector 428 is stationary relative to the support device 402. If the lower pallet 414 is driven to move from the back to the front, an upper part of the endless belt 412 coupled with the upper pallet 410 is also driven to move from the back to the front, that is, the upper part of the endless belt 412 coupled with the upper pallet 410 moves synchronously with the lower pallet 414, thereby driving the upper pallet 410 to move synchronously in the front-back direction. In this way, the long distance back and forth movement of the upper pallet 410 relative to the support device 402 can be implemented.
To implement the long distance back and forth movement of the upper pallet 410 relative to the support device 402, the scanning table provided by the present disclosure is provided with a double-layer pallet structure. The double-layer pallet structure includes the upper pallet 410 and the lower pallet 414. The upper pallet 410 is coupled with the support device 402 by the lower pallet 414. The driving device drives the lower pallet 414 to move in the front-back direction relative to the support device 402. The lower pallet 414 further drives the upper pallet 410 to move in the front-back direction relative to the lower pallet 414. In this way, a back and forth moving distance of the upper pallet 410 relative to the support device 402 is equal to a sum of a back and forth moving distance of the upper pallet 410 relative to the lower pallet 414 and a back and forth moving distance of the lower pallet 414 relative to the support device 402. In this way, the upper pallet 410 is not too long, the deflection of the upper pallet 410 is not increased because the length of the upper pallet 410 is not increased, the support stability of the upper pallet 410 is improved, and the long distance back and forth movement of the upper pallet 410 is implemented while satisfying scanning requirements.
In addition, single-stage driving of the opening belt 416 is applied in the driving device. The lower pallet 414 is driven by the first driving wheel 423 cooperated with the opening belt 416. At this time, on one hand, the opening belt 416 is rigider than the endless belt 412, the gap control is more accurate and the transmission precision can be improved; and on the other hand, since the transmission precision of a belt is inversely proportional to its length, the length of the opening belt 416 is substantially half of the endless belt 412, which greatly improves the transmission precision. Furthermore, the length of the transmission belt is not excessively long due to the reliability of the transmission, and the more the transmission stages, the lower the transmission precision. Therefore, in the present disclosure, the opening belt 416 is directly driven by the first driving wheel 423 coupled with the driving device, thereby effectively shortening the number of transmission stages and improving the transmission precision.
The power component 417 may include an electric motor, or include a combination of an electric motor and a speed reducer. The power component 417 may be a ferromagnetic component. The power component 417 may be coupled to the transmission shaft 419 by a coupling device (or coupler) 418. Or the power component 417 may directly drive the transmission shaft 419.
As shown in
Therefore, by the reversing mechanism and the transmission shaft 419, the power component 417 may be disposed at the back end of the scanning table and away from the first driving wheel 423 on the opening belt 416. Due to the limitation of the driving manner, to implement the long distance movement of the opening belt 416 from the back to the front, so that the lower pallet 414 is driven forward into the imaging device by the opening belt 416, the first driving wheel 423 is disposed at the front end of the opening belt 416, that is, the first driving wheel 423 is disposed close to the imaging device. However, as described above, the power component 417 is the ferromagnetic component, and the imaging device includes a magnetic component such as the magnet 400. If the power component 417 is disposed close to the imaging device, the uniformity of the magnetic field and the linearity of the gradient field can be affected. Therefore, by the reversing mechanism and the transmission shaft 419, the power component 417 is disposed at the back end of the scanning table and away from the imaging device, thereby avoiding affecting the imaging device.
The second driving wheel 422 and the third driving wheel 421 may both be spiral bevel gears, or may both be straight tooth bevel gears, to improve transmission reliability and meet the reversing demand. That is, if the second driving wheel 422 is a spiral bevel gear, the third driving wheel 421 is also a spiral bevel gear; and if the second driving wheel 422 is a straight tooth bevel gear, the third driving wheel 421 is also a straight tooth bevel gear. Those skilled in the art may select other types of driving wheels as the second driving wheel 422 and the third driving wheel 421 as needed.
It is understood that, in view of the direction in which the first driving wheel 423 and the transmission shaft 419 are substantially at a right angle to each other, the reversing mechanism in the present disclosure may also be a right angle reducer. One end of the right angle reducer is coupled to the transmission shaft 419, and the other end of the right angle reducer is coupled to the first driving wheel 423.
As shown in
The front connector 425 and the back connector 415 may be disposed in accordance with the structure of the opening belt 416. For example, the opening belt 416 is a synchronous belt or a chain, and the first driving wheel 423 is correspondingly a synchronous pulley or a chain wheel, and both the front connector 425 and the back connector 415 are cooperated with the opening belt 416.
In some examples, the scanning table further includes a first transmission wheel 424 and a second transmission wheel 427 respectively on the front and back sides of the first driving wheel 423. Both the first transmission wheel 424 and the second transmission wheel 427 are disposed above the first driving wheel 423 and under/below the opening belt 416 to respectively guide the front and back portions of the opening belt 416 to extend upward, such that the front and back portions of the opening belt 416 are above the first driving wheel 423. The front portion of the opening belt 416 before the first driving wheel 423 is referred to as a front opening belt. The back portion of the opening belt 416 after the first driving wheel 423 is referred to as a back opening belt. At this case, the front connector 425 is fixedly coupled to a front end of the front opening belt, and the back connector 415 is fixedly coupled to a back end of the back opening belt. The first driving wheel 423 is positioned above a portion of the opening belt 416 that is between the front opening belt and the back opening belt. That is, the opening belt 416 has a concave shape with the portion of the opening belt below the first driving wheel 423 and the front opening belt and the back opening belt in a plane above the first driving wheel 423.
By the first transmission wheel 424 and the second transmission wheel 427, the rotation of the first driving wheel 423 is converted into a linear movement of the opening belt 416 in the front-back direction, so as to drive the lower pallet 414 to move in the front-back direction. Moreover, the first transmission wheel 424 and the second transmission wheel 427 are disposed higher than the first driving wheel 423, so that “sinking” mounting of the first driving wheel 423 may be implemented. In this way, the first driving wheel 423 is prevented from protruding upward and colliding against the lower pallet 414, thereby preventing the first driving wheel 423 from interfering with the lower pallet 414.
On the basis of the above, a third transmission wheel 413 and a fourth transmission wheel 426 are respectively hinged at the front and back ends of the lower pallet 414, and the endless belt 412 is sleeved on the lower pallet 414. An axis of the third transmission wheel 413 is in the left-right direction of the scanning table. An axis of the fourth transmission wheel 426 is in the left-right direction of the scanning table. In this way, the endless belt 412 may be driven by the third transmission wheel 413 and the fourth transmission wheel 426 to rotationally move in the front-back direction.
In some examples, the endless belt 412 is divided into the upper part and a lower part. The lower part of the endless belt 412 is fixedly coupled to the support device 402 by the first connector 428, and the upper part of the endless belt 412 is fixedly coupled to the upper pallet 410 by a second connector 411. The first connector 428 is disposed on a front end of the lower part the endless belt 412, and the second connector 411 is disposed at a back end of the upper part of the endless belt 412.
Those skilled in the art may set the endless belt 412 as a synchronous belt or a chain as needed. At this time, the third transmission wheel 413 and the fourth transmission wheel 426 are both provided as synchronous pulleys or chain wheels to cooperate with the endless belt 412. If the endless belt 412 is provided as a synchronous belt, the third transmission wheel 413 and the fourth transmission wheel 426 are both provided as synchronous pulleys. If the endless belt 412 is provided as a chain, the third transmission wheel 413 and the fourth transmission wheel 426 are both provided as chain wheels.
It is noted that the third transmission wheel 413 and the fourth transmission wheel 426 are not limited to synchronous pulleys and chain wheels, and the endless belt 412 is not limited to a synchronous belt and a chain. If the third transmission wheel 413, the fourth transmission wheel 426, and the endless belt 412 are defined as a group of transmission mechanism, the number of groups of transmission mechanism may be one, but not limited to one, and may be two or more.
Similarly, the first driving wheel 423 is not limited to a synchronous pulley and a chain wheel, and the opening belt 416 is not limited to a synchronous belt and a chain. If the first driving wheel 423 and the opening belt 416 are defined as a group of transmission mechanism, the number of groups of transmission mechanism may be one, but not limited to one, and may be two or more.
Further, the third driving wheel 421 and the second driving wheel 422 may be spiral bevel gears, but not limited to spiral bevel gears, or may be straight tooth bevel gears, or other forms of driving wheels.
As shown in
In the second stage transmission, the third transmission wheel 413 and the fourth transmission wheel 426 are hingedly fixed to both ends of the lower pallet 414 by a hinge shaft 429 and a hinge shaft 430, respectively, and the endless belt 412 is sleeved on the third transmission wheel 413 and the fourth transmission wheel 426. A portion of the upper part of the endless belt 412 close to the fourth transmission wheel 426 is coupled to the upper pallet 410 by the second connector 411. A portion of the lower part of the endless belt 412 close to the third transmission wheel 413 is coupled to the support device 402 by the first connector 428.
As shown in
Since the support device 402 and the first connector 428 fixed on the support device 402 are stationary relative to the ground, a portion of the upper part of the endless belt 412 at which the endless belt 412 is coupled with the first connector 428 is stationary relative to the ground. When the lower pallet 414 is driven to move back and forth, the third transmission wheel 413 and the fourth transmission wheel 426 fixed on the lower pallet 414 are also driven to move back and forth, and the endless belt 412 sleeved on the third transmission wheel 413 and the fourth transmission wheel 426 is also driven to move synchronously with the lower pallet 414. Since the portion of the upper part of the endless belt 412 at which the endless belt 412 is coupled with the first connector 428 is stationary relative to the ground, the portion of the upper part of the endless belt 412 at which the endless belt 412 is coupled with the first connector 428 is driven to move back and forth relative to the lower pallet 414, such that the entire endless belt 412 is driven to move back and forth relative to the lower pallet 414. The back and forth movement of the entire endless belt 412 further drives the second connector 411 fixed on the upper part of the endless belt 412 to move back and forth relative to the lower pallet 414. Finally, the second connector 411 drives the upper pallet 410 to move back and forth relative to the lower pallet 414.
According to the above motion principle, the lower pallet 414 moves back and forth relative to the support device 402 with a first distance, and the upper pallet 410 moves back and forth relative to the lower pallet 414 with a second distance. Therefore, the upper pallet 410 moves back and forth relative to the support device 402 with a sum of the first distance and the second distance. In this way, the long distance back and forth movement of the upper pallet 410 can be implemented.
In view of the complicated structure of the medical imaging equipment, only the scanning table is described herein. For other structures of the medical imaging equipment, please refer to the prior art, which will not be enumerated herein.
The present disclosure also provides medical imaging equipment including an imaging device and a scanning table. The scanning table is configured to move a subject into or out of the imaging device. The imaging device is configured to scan a region of interest of the subject. The specific structure of the scanning table may be referred to the above examples, and further details are omitted for brevity.
The scanning table provided by the present disclosure and the medical imaging equipment having the scanning table are described in detail above. The principles and examples of the present disclosure have been described herein with reference to some examples. The description of the above examples is only for the purpose of understanding the core concepts of the present disclosure.
The above description is merely preferred examples of the present disclosure and is not intended to limit the present disclosure in any form. Although the present disclosure is disclosed by the above examples, the examples are not intended to limit the present disclosure. Those skilled in the art, without departing from the scope of the technical scheme of the present disclosure, may make a plurality of changes and modifications of the technical scheme of the present disclosure by the method and technical content disclosed above.
Therefore, without departing from the scope of the technical scheme of the present disclosure, based on technical essences of the present disclosure, any simple alterations, equal changes and modifications should fall within the protection scope of the technical scheme of the present disclosure. Accordingly, other examples are within the scope of the following claims.
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