Abstract: The invention relates to a method for producing a metal foam of at least one first metal that contains the main constituent Mg, Al, Pb, Au, Zn, Ti or Fe in a quantity of at least approximately 80 wt. % in relation to the quantity of the at least one first metal, said method comprising the following steps: (I) providing a semi-finished product comprising a foamable mixture that comprises the at least one first metal and at least one foaming agent, (II) submerging the semi-finished product in a heatable bath comprising a liquid, and (III) heating the semi-finished product in the bath in order to foam the foamable mixture by removing gas from the at least one foaming agent for forming the metal foam. The invention also relates to a metal foam, to a composite material that can be obtained by the method, and to a component comprising the metal foam and/or the composite material.

Abstract: The invention relates to a method for producing a metal foam of at least one first metal that contains the main constituent Mg, Al, Pb, Au, Zn, Ti or Fe in a quantity of at least approximately 80 wt. % in relation to the quantity of the at least one first metal, said method comprising the following steps: (I) providing a semi-finished product comprising a foamable mixture that comprises the at least one first metal and at least one foaming agent, (II) submerging the semi-finished product in a heatable bath comprising a liquid, and (III) heating the semi-finished product in the bath in order to foam the foamable mixture by removing gas from the at least one foaming agent for forming the metal foam. The invention also relates to a metal foam, to a composite material that can be obtained by the method, and to a component comprising the metal foam and/or the composite material.

Abstract: Systems and methods are provided for detecting proximity to and collisions with medical devices. A capacitive sensor element includes a compressible insulator layer that has a first conductor track arrangement on a first surface and a second conductor track arrangement on a second surface. The second surface lies opposite the first surface. The sensor apparatus further includes an evaluation device for repeated acquisition of a capacitance value of the sensor element. The evaluation device is configured to output a proximity signal when the respective capacitance value reaches or exceeds a predetermined first threshold value, and is configured to output a collision signal when the respective capacitance value reaches or exceeds a predetermined second threshold value. The second predetermined threshold value is higher than the first predetermined threshold value.

Abstract: A robotic medical apparatus includes a kinematic chain including a stand unit, an articulation device, a positioning device, and a positionable end effector. The apparatus further includes a controller to control the positioning device. The robotic medical apparatus includes a measurement system to determine a force and/or a torque. The force and/or the torque is essentially acting at one point in the kinematic chain. A measurement signal from the measurement system is transmittable to the controller. The controller is configured to determine the force and/or torque that is acting, and as a function of a current position and/or of a current kinematic state, to determine a nominal force and/or a nominal torque. As a function of the difference between the force that is acting and/or the torque that is acting that has been determined and the nominal force and/or the nominal torque that has been determined, a collision is detected.

Abstract: A medical examination, treatment, or examination and treatment device is provided. The medical examination, treatment, or examination and treatment device includes a cover panel. The cover panel includes a sensor for detecting a collision. The sensor includes a first plate mounted on the examination, treatment, or examination and treatment device, and a second plate mounted on the inside of the cover panel and spaced apart from the first plate. Spring elements are disposed between the first plate and the second plate.

Abstract: Systems and methods are provided for detecting proximity to and collisions with medical devices. A capacitive sensor element includes a compressible insulator layer that has a first conductor track arrangement on a first surface and a second conductor track arrangement on a second surface. The second surface lies opposite the first surface. The sensor apparatus further includes an evaluation device for repeated acquisition of a capacitance value of the sensor element. The evaluation device is configured to output a proximity signal when the respective capacitance value reaches or exceeds a predetermined first threshold value, and is configured to output a collision signal when the respective capacitance value reaches or exceeds a predetermined second threshold value. The second predetermined threshold value is higher than the first predetermined threshold value.

Abstract: An apparatus assembly of a medical apparatus is equipped for collision detection by attaching a polyvinylidene fluoride (PVDF) cover assembly to at least one rigid surface of the apparatus assembly, with a resilient material between the PVDF cover assembly and the rigid surface. The PVDF assembly is composed of a PVDF foil with electrically conductive layers on opposite sides thereof. A protective layer covers the PVDF cover assembly. Electrical leads are connected to the conductive layers, and the piezoelectric property of the PVDF foil produces a voltage across the leads when a force associated with a collision acts on the PVDF foil. A detection circuit detects this voltage and initiates an appropriate response to the collision.

Abstract: A method for controlling a movement of an x-ray apparatus is provided. The x-ray apparatus has a C-arm with an x-ray source and an x-ray detector disposed opposite one another, an actuator for positioning the C-arm relative to an examination region of an examination object supported on a support facility, a control facility for controlling the x-ray source and the x-ray detector and the actuator, and an operating facility with a display apparatus and an operating unit. The display apparatus displays an image representing a part of the examination object and a target location of the C-arm being determined as a function of an input at the operating unit. The target location has a target position and a target alignment of the C-arm. A controlled variable of the actuator is determined and supplied to the control facility for controlling the actuator.

Abstract: A robotic medical apparatus includes a kinematic chain including a stand unit, an articulation device, a positioning device, and a positionable end effector. The apparatus further includes a controller to control the positioning device. The robotic medical apparatus includes a measurement system to determine a force and/or a torque. The force and/or the torque is essentially acting at one point in the kinematic chain. A measurement signal from the measurement system is transmittable to the controller. The controller is configured to determine the force and/or torque that is acting, and as a function of a current position and/or of a current kinematic state, to determine a nominal force and/or a nominal torque. As a function of the difference between the force that is acting and/or the torque that is acting that has been determined and the nominal force and/or the nominal torque that has been determined, a collision is detected.

Abstract: A medical examination, treatment, or examination and treatment device is provided. The medical examination, treatment, or examination and treatment device includes a cover panel. The cover panel includes a sensor for detecting a collision. The sensor includes a first plate mounted on the examination, treatment, or examination and treatment device, and a second plate mounted on the inside of the cover panel and spaced apart from the first plate. Spring elements are disposed between the first plate and the second plate.

Abstract: An apparatus assembly of a medical apparatus is equipped for collision detection by attaching a polyvinylidene fluoride (PVDF) cover assembly to at least one rigid surface of the apparatus assembly, with a resilient material between the PVDF cover assembly and the rigid surface. The PVDF assembly is composed of a PVDF foil with electrically conductive layers on opposite sides thereof. A protective layer covers the PVDF cover assembly. Electrical leads are connected to the conductive layers, and the piezoelectric property of the PVDF foil produces a voltage across the leads when a force associated with a collision acts on the PVDF foil. A detection circuit detects this voltage and initiates an appropriate response to the collision.

Abstract: On a medical diagnosis and/or intervention device having a movable component, collision sensors are to be arranged without the cabling outlay becoming too high. This is made possible by the collision sensors being capable of sending signals wirelessly. The voltage supply can also be provided wirelessly along a section by using e.g. a slip ring.

Abstract: An X-ray apparatus is provided. The Xpray apparatus has a C-arm on which an X-ray source and an X-ray detector can be mounted opposite one another, at least one actuator for positioning the C-arm relative to a patient table, and a control device for controlling the actuator. The X-ray apparatus includes at least one sensor which detects a deformation of the C-arm at a first position of the C-arm and converts it into an output signal, the deformation of the C-arm being influenceable by a force exerted by an operator and applied directly or indirectly at a second position on the C-arm. The control device influences the actuator as a function of the output signal of the sensor. A method for controlling the movement of an X-ray apparatus is also described.

Abstract: A measurement arrangement comprises a clock generator (11) which can be coupled to an emitting ultrasonic transducer (13) and a mixing arrangement (12) for providing a first mixer output signal (SO1). The mixing arrangement (12) has a first input (18) which can be coupled to a receiving ultrasonic transducer (14) and a second input (19) which is coupled to the clock generator (11).

Abstract: An operating unit for a medical device is proposed. The operating unit has at least one display, at least one transparent, touch-sensitive first input field, and at least one transparent, touch-sensitive second input field. The at least one second input field is disposed between the at least one display and the at least one first input field. At least one device provides a haptically perceivable feedback after successful operation of the operating unit.

Abstract: A measurement arrangement comprises a clock generator (11) which can be coupled to an emitting ultrasonic transducer (13) and a mixing arrangement (12) for providing a first mixer output signal (SO1). The mixing arrangement (12) has a first input (18) which can be coupled to a receiving ultrasonic transducer (14) and a second input (19) which is coupled to the clock generator (11).

Abstract: A method, computer readable medium, and a system for reducing power consumption of an at least partially resonant actuator system includes adjusting a driving system with an actuator controller computing device configured to provide a driving signal including a delay interval during a transition in the driving signal. The driving system provides the driving signal with the delay interval to an at least one partially resonant actuator device.

Abstract: A method, computer readable medium, and system for controlling velocity of an at least partially resonant actuator system in accordance with embodiments of the present invention includes determining with an actuator controller computing device a sequence of full bridge and half bridge outputs to control an output velocity of an at least partially resonant actuator device. The actuator controller computing device controls a driver system to output a driving signal based on the determined sequence of full bridge and half bridge outputs. The driver system provides the driving signal to the at least one at least partially resonant actuator device.

Abstract: An X-ray apparatus is provided. The Xpray apparatus has a C-arm on which an X-ray source and an X-ray detector can be mounted opposite one another, at least one actuator for positioning the C-arm relative to a patient table, and a control device for controlling the actuator. The X-ray apparatus includes at least one sensor which detects a deformation of the C-arm at a first position of the C-arm and converts it into an output signal, the deformation of the C-arm being influenceable by a force exerted by an operator and applied directly or indirectly at a second position on the C-arm. The control device influences the actuator as a function of the output signal of the sensor. A method for controlling the movement of an X-ray apparatus is also described.

Abstract: An operating unit for a medical device is proposed. The operating unit has at least one display, at least one transparent, touch-sensitive first input field, and at least one transparent, touch-sensitive second input field. The at least one second input field is disposed between the at least one display and the at least one first input field. At least one device provides a haptically perceivable feedback after successful operation of the operating unit.