Abstract: A folding hose storage rack is disclosed. The rack includes two spaced apart support members with each support member having a vertical member configured to rotate about a vertical axis, an upper arm extending outward from the vertical member, a lower arm extending outward from the vertical member, where the lower arm is aligned under the upper arm, and a boss along a lower edge of the lower arm. In addition, the rack includes a retainer having intersecting slots such that each slot is configured to receive the boss to prevent the support member from rotating. Each support member is configured to lift up to remove the boss from the intersecting slots, rotate to a desired position, and lower down to insert the boss into a desired slot of the intersecting slots. The intersecting slots form a T-configuration to rotate and secure each supporting arm to either side.

Abstract: An air diverter system for a vacuum excavator is disclosed. In a particular embodiment, the system includes a bag house in communication with a debris tank. In addition, the system includes a filter housing secured to a side of the bag house and a valve housing interposed between the bag house and the filter housing. A valve member is mounted within the valve housing and is configured to rotate about an axis to define at least two different passageways for an air flow. The system also includes a selector for rotating the valve member and selectively aligning the passageway for the airflow between a vacuum pump inlet and either the filter housing or the bag house.

Abstract: A device for detecting the three-dimensional geometry of objects (9), in particular teeth, includes a handpiece (1) which is provided with at least one position sensor (12) for detecting the change of the spatial position of the handpiece (1), and an optical device (2) having at least one camera (5, 6) for capturing images and at least one light source (3) for at least one projector (4). The position sensor (12) in the handpiece (1) initially determines the size of the change of the spatial position of the device. It is determined therefrom, how many pictures the camera (5, 6) can take in a defined time unit.

Abstract: A device for recording images of three-dimensional objects (10), in particular teeth, has a light source (22) and a camera (32) for recording images of the object (10), whereby in the beam path of the light source (22), at least one transparent vehicle (36, 37) is arranged with a pattern that is projected onto the object (10). The vehicle (36, 37) has sections that are offset with respect to one another in the direction of the beam path. As an alternative or in addition, at least two vehicles (36, 37) can be offset with respect to one another in the direction of the beam path.

Abstract: A system and method to excavate and fill is disclosed. The system includes a canister adapted to receive and store excavated material. In addition, a plurality of blades are mounted inside of the canister about a horizontal shaft proximate a bottom end of the canister. A motor is adapted to rotate the plurality of blades to move the excavated material stored in the canister to the bottom end of the canister and a blower is adapted to blow the excavated material at the bottom end of the canister out of an opposing side of the canister through a discharge port. The canister includes a downward sloping lip disposed above the plurality of blades, where the downward sloping lip funnels the excavated material on to a downwardly rotating blade of the plurality of blades.

Abstract: An air diverter system for a vacuum excavator is disclosed. In a particular embodiment, the system includes a bag house in communication with a debris tank. In addition, the system includes a filter housing secured to a side of the bag house and a valve housing interposed between the bag house and the filter housing. A valve member is mounted within the valve housing and is configured to rotate about an axis to define at least two different passageways for an air flow. The system also includes a selector for rotating the valve member and selectively aligning the passageway for the airflow between a vacuum pump inlet and either the filter housing or the bag house.

Abstract: A method for acquiring three-dimensional images of objects uses two cameras having acquisition areas that overlap each other. In the course of a calibration method, a group of epipolar lines associated with each other is determined for each of the cameras. A specified random image is projected onto the object to be imaged. For each pixel of the camera, a first environment is determined, an associated first epipolar line is determined, and for the first epipolar line an associated second epipolar line of the second camera is determined. For all pixels of the image of the second camera that are located on the second epipolar line, a second environment congruent to the first environment is determined. The intensity values of the first and the second environments are compared with each other and a measure of agreement is calculated. A spatial position is determined by use of the previously determined transformation.

Abstract: The present invention provides a combination therapy for effectively treating and/or preventing diseases associated with cells expressing CLDN18.2, including cancer diseases such as gastric cancer, esophageal cancer, pancreatic cancer, lung cancer, ovarian cancer, colon cancer, hepatic cancer, head-neck cancer, and cancer of the gallbladder and metastases thereof.

Abstract: A shaker screen comprises a frame that has a plurality of opposing sides. The shaker screen also comprises a screen assembly attached to the frame. In addition, each side of the shaker screen comprises a tubular member having an inner edge, an outer edge, and defining a central axis. Further, a horizontal plane intersects the central axis, the outer edge, and the inner edge of each side.

Abstract: A folding hose storage rack is disclosed. The rack includes two spaced apart support members with each support member having a vertical member configured to rotate about a vertical axis, an upper arm extending outward from the vertical member, a lower arm extending outward from the vertical member, where the lower arm is aligned under the upper arm, and a boss along a lower edge of the lower arm. In addition, the rack includes a retainer having intersecting slots such that each slot is configured to receive the boss to prevent the support member from rotating. Each support member is configured to lift up to remove the boss from the intersecting slots, rotate to a desired position, and lower down to insert the boss into a desired slot of the intersecting slots. The intersecting slots form a T-configuration to rotate and secure each supporting arm to either side.

Abstract: A method of capturing three-dimensional (3D) information on a structure includes obtaining a first image set containing images of the structure with at least one physical camera located at a first position, the first image set comprising one or more images; reconstructing 3D information from the first image set; obtaining 3D information from a virtual camera out of an existing global model of the structure; determining correspondences between the obtained 3D information and the reconstructed 3D information; determining camera motion between the obtained 3D information and the reconstructed 3D information from the correspondences; and updating the existing global model by entering the obtained 3D information using the determined camera motion.

Abstract: A method of integrating new information from depth maps into an existing three-dimensional representation of an object surface, the representation being a truncated signed distance function (TSDF) noted in individual voxels, the TSDF indicating, to respective coordinates within a defined volume, a distance to a next surface, includes obtaining a depth map showing the object, the depth map containing values from measurements; and integrating new information from the depth map into the existing TSDF, wherein each individual voxel affected by the depth map within the TSDF is updated and the update for each updated voxel is selected from the group of a front update if said voxel is near the outer side, a rear update if the voxel is near the inner side, and an ambiguous update, each kind of update leads to a different weighting for the updated value within the voxel.

Abstract: A method and system capturing three-dimensional information of a scene on a structure includes operating a light pattern projector to project a known light pattern onto the scene; using at least two cameras, taking images of the scene, the images being two-dimensional images taken chronologically synchronous; using first and second images, and the known position and orientation of the cameras with respect to each other, extracting a first depth map of the scene; using the first image, the known light pattern, and the known position and orientation of the first camera and the light pattern projector with respect to each other, extracting a second depth map of the scene; and using the extracted first depth map and the extracted second depth map of the scene together to make a 3D measurement of the scene.

Abstract: In a method for displaying at least one property of an optically determined surface geometry of at least one three-dimensional object, in particular a tooth, on a display, in particular a computer screen, a defined region of the surface geometry is monitored to ascertain whether a defined criterion has been fulfilled. An amount of optically determined data of the defined region is a criterion. A number of defined regions of the surface geometry are assigned a property when all the regions of the number meet the criterion. The property is displayed graphically in a defined manner, wherein different properties are graphically displayed in a differing manner.

Abstract: A method for capturing at least one sub-region of a three-dimensional geometry of at least one object, for the purpose of updating an existing virtual three-dimensional geometry of the sub-region, optionally after elements of the object present in the sub-region have been modified, removed and/or added, wherein the method includes the following steps: a) providing the existing virtual three-dimensional geometry of the object, for example, from an earlier image capture, b) capturing of two-dimensional images from which spatial information of the three-dimensional geometry of the objects is obtained, c) automatic addition of spatial information obtained to existing spatial information, if applicable d) updating the existing virtual three-dimensional geometry of the sub-region of the object based on added information, e) optionally repeating the process from step b).

Abstract: A device for detecting the three-dimensional geometry of objects (9), in particular teeth, includes a handpiece (1) which is provided with at least one position sensor (12) for detecting the change of the spatial position of the handpiece (1), and an optical device (2) having at least one camera (5, 6) for capturing images and at least one light source (3) for at least one projector (4). The position sensor (12) in the handpiece (1) initially determines the size of the change of the spatial position of the device. It is determined therefrom, how many pictures the camera (5, 6) can take in a defined time unit.

Abstract: Provided is a rescue request signal processing device connected with a repeater and including a signal detector configured to detect identification information of a wireless communication terminal from an uplink signal outputted from the wireless communication terminal; a signal strength information generator configured to generate strength information of the uplink signal of the wireless communication terminal when the detected identification information of the wireless communication terminal is identical with identification information of a wireless communication terminal included in a request signal for location information transmitted from a location information requesting device; and a transmitter configured to transmit the strength information of the uplink signal and at least one of location information and identification information of the repeater to a location information server.

Abstract: In the case of a method for optical acquisition of the three-dimensional geometry of objects, in particular teeth (4), with a scanner (14), which has a scanning head (13), the three-dimensional geometry that is acquired in a virtual three-dimensional space (1) in the course of scanning is noted. In this case, in the course of scanning, positions of a defined scanner geometry (2) of the scanner (14), in particular of the scanning head (13), are noted relative to the object (4) that is acquired, and, moreover, an area (6) in which the defined scanner geometry (2) is or was located is determined. The determined area (6) is marked, for example as “empty,” in the virtual space (1).

Abstract: A holding device with a base element for a handpiece of an intraoral scanner, which has a head area (3), has a receiving area (5) of the base element (1), in which the head area (3) can be snugly accommodated at least partially. The receiving area (5) has an interior (8) with at least two holding areas (10, 11), which are arranged essentially opposite to one another.

Abstract: A repeater using a digital filter is disclosed. The repeater comprises a MUX filter for filtering an RF signal received through an antenna or a signal to be transmitted through the antenna; a low noise amplifier for lowering noise of the signal filtered by the MUX filter; a down converter for converting the signal outputted from the low noise amplifier into an IF band signal to digitalize the signal; a digital filter for filtering the digital signal outputted form the down converter based on parameters inputted by a user; a filtering controller for controlling the digital filter by using a filtering coefficient calculated based on the parameters; an up converter for converting the signal filtered by the digital filter into an RF band signal; and a high power amplifier for amplifying the signal outputted from the up converter to a high power signal.