Abstract: The present disclosure provides a spliced and molded pillow core and a molding method thereof. The spliced and molded pillow core includes a spliced pillow core molded by splicing a plurality of splicing blocks, the spliced pillow core is integrally formed by molding, and base materials of at least two splicing blocks are different. The present disclosure adopts a differentiated base material for splicing and molding, so as to provide a pillow area with abundant elastic differences to the pillow core, and to meet the demand combining high rebounding and slow rebounding; and the pillow core is more comfortable to use. By combining an adhesive with tenon-and-mortise, the molded structure of the pillow core is more reliable and stable, the effective service life is prolonged, and at the same time the division of the pillow area is more reasonable, so as to provide the abundant differentiated support demand.

Abstract: Disclosed are an integrated mold-pressing pillowcase and a mold-pressing forming device. The integrated mold-pressing pillowcase includes a pillowcase top layer, a pillowcase bottom layer and a pillowcase peripheral wall, the pillowcase peripheral wall is arranged between the pillowcase top layer and the pillowcase bottom layer, the pillowcase bottom layer is provided with a window position for carrying a pillow inner, and the pillowcase top layer, the pillowcase bottom layer and the pillowcase peripheral wall are integrally mold-formed by polyester fabric. The present invention adopts a pillowcase design of integrated mold-pressing by the polyester fabric, which greatly simplifies the production process of the pillowcase, meets the demand for the built-in stability of the pillow inner, and has the characteristics of good air permeability, comfortable contact and the like.

Abstract: When a force sensor on a robot arm detects that the force of contact between an end of a calibration device and a calibration plate reaches a threshold, the robot arm stops, and the end of the calibration device performs marking at the contact position between the end of the calibration device and the calibration plate. The robot arm moves upward and stops at a position where the end of the robot arm is at a predetermined height. At this position, a camera at the end of the robot arm photographs marks on the calibration plate, records the coordinates of the marks in the camera coordinate system, and records the coordinates of the end of the calibration device in the robot coordinate system. A calibration transformation matrix is calculated according to the recorded coordinates of at least three marks.

Abstract: When a force sensor on a robot arm detects that the force of contact between an end of a calibration device and a calibration plate reaches a threshold, the robot arm stops, and the end of the calibration device performs marking at the contact position between the end of the calibration device and the calibration plate. The robot arm moves upward and stops at a position where the end of the robot arm is at a predetermined height. At this position, a camera at the end of the robot arm photographs marks on the calibration plate, records the coordinates of the marks in the camera coordinate system, and records the coordinates of the end of the calibration device in the robot coordinate system. A calibration transformation matrix is calculated according to the recorded coordinates of at least three marks.

Abstract: A robot hand-eye calibration method includes: controlling a tail end of a robot arm to sequentially move to at least three respective positions above a calibration plate; controlling a laser provided on the robot arm, at each position, to project on the calibration plate; recording coordinates, in a robot coordinate system, of an end point of the tail end of the robot arm during projection; controlling a camera on the tail end of the robot arm to photograph the projection on the calibration plate; recording the coordinates of the projection in the camera coordinate system; and calculating a calibration transformation matrix, according to the coordinates recorded, of at least three projections on the calibration plate in the camera coordinate system and respective coordinates of the end point of the tail end of the robot arm in the robot coordinate system during each respective projection.

Abstract: Radio-frequency (RF) coil apparatus for magnetic resonance imaging has a base and an RF coil, wherein the base has a sliding base guide structure and a guide cavity, the RF coil has a sliding coil structure fitting the sliding base guide structure, and an electric cable of the RF coil is accommodated in the guide cavity and can move in the guide cavity. One end of the electric cable is fixed to the RF coil by a first fixing bracket, and another end of the electric cable is fixed to the base by a second fixing bracket so that a predetermined length of the cable projects from the base.

Abstract: Radio-frequency (RF) coil apparatus for magnetic resonance imaging has a base and an RF coil, wherein the base has a sliding base guide structure and a guide cavity, the RF coil has a sliding coil structure fitting the sliding base guide structure, and an electric cable of the RF coil is accommodated in the guide cavity and can move in the guide cavity. One end of the electric cable is fixed to the RF coil by a first fixing bracket, and another end of the electric cable is fixed to the base by a second fixing bracket so that a predetermined length of the cable projects from the base.

Abstract: A shoulder coil for a magnetic resonance system includes a receiving part. The shoulder coil also includes a transmitting part used for coupling a radio-frequency magnetic field of a body coil of the magnetic resonance system.

Abstract: In a method for acquiring magnetic resonance signals from a first shoulder or an opposite second shoulder of a patient, a shoulder coil anterior part and a shoulder coil posterior part are provided. A base plate is engageable with a moveable support element connecting the shoulder coil posterior part to the base plate to permit lateral movement and 90 degree rotation of the shoulder coil posterior part. With the base plate beneath the patient, the shoulder coil posterior part is placed below the first shoulder and the shoulder coil anterior part is placed above the first shoulder to permit acquisition of magnetic resonance measurements. To acquire signals from the opposite second shoulder, the shoulder coil posterior part is moved across the base plate to be positioned beneath the second shoulder and is rotated by 90 degrees. The shoulder coil anterior part is placed above the rotated shoulder coil posterior part.

Abstract: A shoulder coil for a magnetic resonance system includes a receiving part. The shoulder coil also includes a transmitting part used for coupling a radio-frequency magnetic field of a body coil of the magnetic resonance system.

Abstract: Improved patient comfort is provided by a symmetric local coil arrangement designed to support the production of an MRT image of a shoulder, wherein the housing of the local coil arrangement is composed of two separable parts. The symmetric local shoulder coil arrangement is designed to be useable for either of a right or left shoulder of a human subject by rotating the local coil arrangement about a rotational axis that is parallel to an axis of symmetry of the local shoulder coil and perpendicular to anterior and posterior members of the shoulder coil.

Abstract: A local coil includes a body portion. The body portion includes an inner conductor layer. The local coil further includes at least one elastic wing. The body portion and the at least one elastic wing form an accommodating space for accommodating a body part to be inspected.

Abstract: In a system having a magnetic resonance imaging (MRI) apparatus and MRI-monitored medical equipment, the MRI-monitored medical equipment has an inductive coil built into the equipment that receives magnetic resonance signals from a subject and generates inductive electromagnetic signals according to the received magnetic resonance signals. The magnetic resonance imaging system has at least one reception coil that is positioned externally of the MRI-monitored medical equipment and that is connected to the magnetic resonance imaging system via a cable. The reception coil receives the electromagnetic signals that are generated by the inductive coil that is built into the medical equipment.

Abstract: A receiving device for an MRI (magnetic resonance imaging) system has multiple receiving coils. In the same imaging acceleration direction, a junction region is formed between adjacent receiving coils. An additional receiving coil is arranged on the junction region. The additional receiving coil covers at least partially a line of strong phase variation in sensitivity at the boundary of said junction region. This receiving device alleviates the problem of poor sensitivity to MRI signals in the junction region in the imaging acceleration direction, so as to improve the imaging quality in the junction region, and thus improving the overall imaging quality.

Abstract: Improved patient comfort is provided by a local coil arrangement designed to support the production of an MRT image of a shoulder, wherein the housing of the local coil arrangement is composed of two separable parts.

Abstract: In a method and magnetic resonance (MR apparatus for reducing aliasing artifacts in the imaging for MR-monitored high intensity focused ultrasound HIFU therapy, a primary coil is used to receive the MR signals, and an additional coil is provided to receive interfering MR signals that form aliasing artifacts in the MR-monitored HIFU therapy imaging. The MR signals received by the primary coil and the interfering MR signals received by the additional coil are concurrently acquired. The interfering MR signals received by the additional coil are removed from the MR signals received by the primary coil. MR images are generated based on the MR signals with the interfering MR signals removed. Aliasing artifacts caused by the interfering MR signals thus are removed from the MR images without reducing the resolution of the scanned body parts in the MR images. In addition, the MR scanning time can be—maintained by using a proper phase oversampling technology in the concurrent signal acquisition.

Abstract: In a high field magnetic resonance imaging apparatus and a method for obtaining signals having a high signal-to-noise ratio with the receiving coil thereof, the apparatus has at least a basic magnet and a receiving coil, the basic magnet generating a basic magnetic field, and the receiving coil being disposed within the basic magnetic field and forming an accommodating cavity. The accommodating cavity of the receiving coil is perpendicular to the direction of the basic magnetic field and is positioned in the field of view of the apparatus. The receiving coil is a loop type coil. The apparatus can further have a bracket for fixing the receiving coil. In the method, a receiving coil is used to receive signals in a magnetic field, wherein the receiving coil is perpendicular to the direction of the magnetic field. By using the apparatus and the corresponding method since the receiving coil can have a loop type design, the signal-to-noise ratio is increased.

Abstract: A magnetic resonance coil has an antenna portion for accommodating a body part to be examined, the antenna portion is formed by a number of constituent units connected in series, the positions between various constituent units are relatively movable. By moving the positions between the constituent units, a portion of the area between at least two constituent units overlaps. By increasing or reducing the number of the constituent units, or by adjusting the overlapped area between the constituent units, one pair or a number of pairs of the constituent units are made to overlap completely, so as to achieve the adjustment of the size of the antenna portion to accommodate a body part to be examined, and to make said antenna portion as close as possible to the body part to be examined, so as to obtain a signal with a relatively high signal-to-noise ratio, and to obtain a relatively high imaging quality.