This method for manufacturing an electronic device comprises: a first substrate arrangement step in which a plurality of electronic components (1) having characteristics that satisfy a prescribed condition are held in an arrayed state on a first surface of each of a plurality of first substrates (21), the prescribed conditions for at least two first substrates (21) among the plurality of first substrates (21) being different from each other; a first reception step in which, for each of the plurality of first substrates (21), a counterpart first substrate (21) is selected from among the plurality of first substrates (21) according to a prescribed first reception sequence and subjected to a step for receiving, on the surface of a first transfer roll (5), the plurality of electronic components (1) held on the first surface along a first direction; and a first provision step in which the first transfer roll (5) and a second substrate (22) are moved to positions where a first rotary shaft (24) of the first transfer roll (5) holding the plurality of electronic components (1) received from the plurality of first substrates (21) on the surface thereof and a second surface of the second substrate (22) are parallel to each other, , and the plurality of electronic components (1) held on the surface of the first transfer roll (5) are provided to the second surface of the second substrate (22).
Provided is a stereolithography device capable of reducing any height difference occurring in a coating film formed on a shaping surface when obtaining a 3D printed object. This stereolithography device comprises: a means for discharging a thixotropic slurry onto a shaping table; a means for horizontally moving a sweeping member in a prescribed sweeping orientation, thereby applying the discharged slurry onto the shaping table by sweeping and forming a slurry film; and a means for exposing a prescribed region of the slurry film according to an exposure pattern created in advance on the basis of 3D shape data. The sweeping member, when in the sweeping orientation, has a front surface facing in the advancement direction of sweeping application and a rear surface facing in the opposite direction. At least near the lowermost end, the advancement-direction interval between the front surface and the rear surface is uniform or decreases toward the lowermost end of the sweeping member, and the advancement-direction distance between the front surface and the rear surface at the lowermost end of the front surface or the lowermost end of the rear surface is 0.9 mm or less.
B22F 10/12 - Formation of a green body by photopolymerisation, e.g. stereolithography [SLA] or digital light processing [DLP]
B28B 1/30 - Producing shaped articles from the material by applying the material on to a core, or other moulding surface to form a layer thereon
B29C 64/106 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material
B29C 64/188 - Processes of additive manufacturing involving additional operations performed on the added layers, e.g. smoothing, grinding or thickness control
Provided is a bacterial cell observation device capable of easily and accurately switching between a dark field and a bright field. A bacterial cell observation device 100 comprises: a dimming plate 6 having a placement region 8 for placing a container 3 in which a bacterial cell 5 and a culture medium 4 are accommodated; a light irradiation mechanism 10 that irradiates the container 3 with light through the dimming plate 6; and an imaging mechanism 20 for imaging the light emitted from the light irradiation mechanism 10 and diffused by the dimming plate 6 or the bacterial cell 5. In a plan view, the placement region 8 and the imaging mechanism 20 are arranged at overlapping positions. The dimming plate 6 can be switched between a transparent state and a diffusion state according to a voltage application state. The light irradiation mechanism 10 emits light in a direction such that the placement region 8 of the dimming plate 6 in the transparent state becomes a dark field of view with respect to the imaging mechanism 20.
A stirring and defoaming device is a stirring and defoaming device of a revolution and rotation type, wherein a vacuum unit for sucking air in each container to bring the inside of each container into a vacuum state includes sealing bodies that seal respective containers, a vacuum generation source, a suction path running toward a revolution center with each container as a starting end, passing through the revolution center to go outside the system, and reaching the vacuum generation source placed outside the system, at least part of the suction path being an independent path from the starting end in association with each container, and at least two or more vacuum measurement units, each provided in an independent path.
A first pre-exposure material layer is formed by drawing and spreading of a first material, a first post-exposure material layer including one or a plurality of first exposed portions is formed by exposure of the first pre-exposure material layer, and one or a plurality of first cured portions remain by removal of one or a plurality of first unexposed portions from the first post-exposure material layer. Next, a second pre-exposure material layer that is in contact with the one or plurality of first cured portions is formed by drawing and spreading of a second material, a second post-exposure material layer including one or a plurality of exposed portions is formed by exposure of the second pre-exposure material layer, and one or a plurality of second cured portions remain by removal of one or a plurality of second unexposed portions from the second post-exposure material layer.
B29C 64/124 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified
B29C 64/194 - Processes of additive manufacturing involving additional operations performed on the added layers, e.g. smoothing, grinding or thickness control during lay-up
A projector of an exposer is movable in a second direction orthogonal to a first direction in a posture inclined so that center positions of two adjacent pixels are offset in the first direction, is configured to switch ON-OFF states of exposure light each time the projector moves a distance corresponding to the drawing pitch in the second direction, exposes a photo-curable material in a predetermined drawing area sequentially for a plurality of strip regions each extending in the second direction, and forms, in a case where a plurality of layers of the photo-curable material are each exposed while being laminated to obtain a three-dimensional object, a joint portion of two adjacent strip regions of the plurality of strip regions and causes an in-plane position of the joint portion to differ between at least two layers of the plurality of layers.
B29C 64/282 - Arrangements for irradiation using multiple radiation means, e.g. micromirrors or multiple light-emitting diodes [LED] of the same type, e.g. using different energy levels
B29C 64/129 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified characterised by the energy source therefor, e.g. by global irradiation combined with a mask
In the present invention, according to an electronic component transfer method: a step in which a plurality of electronic components 15 held on a first base 20 are received on a first transfer roll 4 and/or a step in which a plurality of electronic components 15 held on the first transfer roll 4 are provided to the second base 30 differentiate(s) the gap between the electronic components 15 in the direction following a second axis X3 of the second base 30 with respect to the gap between the electronic components 15 in the direction following a first axis X1 of the first base 20; and a step in which a plurality of the electronic components 15 held on the second base 30 are received on a second transfer roll 11 and/or a step in which a plurality of the electronic components 15 held on the second transfer roll 11 are provided to a third base 40 differentiate(s) the gap between the electronic components 15 in the direction along a third axis X6 of the third base 40 with respect to the gap between the electronic components 15 in the direction along another axis X4 of the second base 30.
H01L 21/52 - Mounting semiconductor bodies in containers
G09F 9/00 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements
G09F 9/33 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements being semiconductor devices, e.g. diodes
H01L 21/50 - Assembly of semiconductor devices using processes or apparatus not provided for in a single one of the groups or
H01L 21/60 - Attaching leads or other conductive members, to be used for carrying current to or from the device in operation
H01L 21/677 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components for conveying, e.g. between different work stations
This printing device is provided with a plurality of printing roll structures (200, 300, 400, 600, 700). Each of the printing roll structures (200, 300, 400, 600, 700) can print ink containing a conductive material, with respect to one base material (3) to be printed placed on a surface plate (110).
A container handling method according to the present invention initially places, at a second location, the last container at a given timing after having taken out, at a placement section, the last container of multi-stage containers, thereafter takes out, at a first location, each of the containers one by one from the top of the multi-stage containers, and places, at the second location, each of the containers on the top one by one so as to configure a multi-stage containers, or takes out, at a given location, each of the containers one by one from the bottom of the multi-stage containers, and places, at the second location, each of the containers on the bottom one by one so as to configure a multi-stage containers. This re-stacking process returns the vertical order of containers in multi-stage containers to the original one. This can prevent reversing of the order in multi-stage containers in which a plurality of containers are stacked.
Provided is a stereolithography device that ensures appropriate supply of build material even when a built object has a large size or area. A stereolithography device for obtaining a three-dimensional built object, comprising: an ejection means capable of ejecting a slurry onto a build table; a sweeping means for sweeping the slurry ejected onto the build table to form a slurry film of a predetermined thickness; an exposure means for exposing the slurry film in accordance with an exposure pattern that is created in advance on the basis of three-dimensional shape data; a monitoring means for monitoring the remaining amount of the slurry in the ejection means during fabrication of the three-dimensional built object; a scraper for applying a shearing stress to the slurry up to an inner surface of the ejection means to scrape the slurry and to make the liquid level of the slurry uniform; a lifting/lowering mechanism for lifting/lowering the scraper; a resupplying means for resupplying additional slurry to the ejection means; and a control means for causing the resupplying means to resupply the additional slurry to the ejection means at a predetermined time in a state in which the remaining amount has become less than a specified value.
B33Y 30/00 - Apparatus for additive manufacturingDetails thereof or accessories therefor
B33Y 50/02 - Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
B29C 64/129 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified characterised by the energy source therefor, e.g. by global irradiation combined with a mask
B29C 64/188 - Processes of additive manufacturing involving additional operations performed on the added layers, e.g. smoothing, grinding or thickness control
The present invention provides an optical shaping apparatus in which good transportability of a shaped object is ensured. A control means causes a transport means to transport a film from a shaping table to an auxiliary table in a state in which a shaped object, which is a laminate of a plurality of slurry films each being an exposed slurry film, is placed on the film, and sequentially switches an air supply port used for supplying air from an air supply means among a plurality of air supply ports in accordance with the state of movement of the shaped object moved by the transport means, so that the shaped object is transported from the shaping table to the auxiliary table in a state in which the shaped object is floating above the shaping table and the auxiliary table together with a part or the whole of the film.
B29C 64/379 - Handling of additively manufactured objects, e.g. using robots
B28B 1/30 - Producing shaped articles from the material by applying the material on to a core, or other moulding surface to form a layer thereon
B29C 64/129 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified characterised by the energy source therefor, e.g. by global irradiation combined with a mask
B29C 64/165 - Processes of additive manufacturing using a combination of solid and fluid materials, e.g. a powder selectively bound by a liquid binder, catalyst, inhibitor or energy absorber
B29C 64/223 - Foils or films, e.g. for transferring layers of building material from one working station to another
B29C 64/282 - Arrangements for irradiation using multiple radiation means, e.g. micromirrors or multiple light-emitting diodes [LED] of the same type, e.g. using different energy levels
B33Y 30/00 - Apparatus for additive manufacturingDetails thereof or accessories therefor
12.
STEREOLITHOGRAPHY DEVICE AND PRODUCTION METHOD FOR 3D PRINTED OBJECT
Provided is a stereolithography device, the exposure accuracy of which is suitably ensured even when a printed object is enlarged. A projector of an exposure means is configured so as to be capable of movement in a second direction orthogonal to a first direction at an orientation inclined relative to the second direction so that the center positions of two adjacent pixels are shifted by a specified rendering pitch in the first direction,, and is configured so that exposure light can be switched between on/off states each time the projector moves a distance equivalent to the rendering pitch in the second direction. The exposure of a specified rendering area of a photocurable material is carried out sequentially for each of a plurality of strip regions extending in the second direction and having a specified rendering width in the first direction, and when obtaining a 3D printed object by layering multiple layers of the photocurable material while curing the respective layers, a joining section joining two adjacent strip regions among the plurality of strip regions is formed, and the in-plane positions of the joining parts in at least two layers among the plurality of layers are different from each other.
B29C 64/393 - Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
B28B 1/30 - Producing shaped articles from the material by applying the material on to a core, or other moulding surface to form a layer thereon
B29C 64/129 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified characterised by the energy source therefor, e.g. by global irradiation combined with a mask
B29C 64/282 - Arrangements for irradiation using multiple radiation means, e.g. micromirrors or multiple light-emitting diodes [LED] of the same type, e.g. using different energy levels
This electronic device has: a second board 10 as a circuit board that exhibits flexibility and/or stretchability; a plurality of anisotropic conduction layers 10a that are disposed on the second board 10 at intervals; and a plurality of LED chips 11 as a plurality of device chips arranged in a prescribed alignment pattern on the plurality of anisotropic conduction layers 10a. The plurality of LED chips 11 are spaced away by a prescribed gap for each LED chip 11 or LED chip 11 group, from an adjacent LED chip 11 or an LED chip 11 group, and are connected to the second board 10 via the corresponding anisotropic conduction layer 10a.
H01L 21/50 - Assembly of semiconductor devices using processes or apparatus not provided for in a single one of the groups or
H01L 21/60 - Attaching leads or other conductive members, to be used for carrying current to or from the device in operation
H01L 21/68 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components for positioning, orientation or alignment
14.
STEREOLITHOGRAPHY APPARATUS AND STEREOLITHOGRAPHY METHOD
According to the present invention, a first pre-exposure material layer is formed by elongating a first material; a first post-exposure material layer, which comprises one or more first exposed portions, is formed by exposing the first pre-exposure material layer to light; and one or more first cured portions are caused to remain by removing one or more first unexposed portions from the first post-exposure material layer. Subsequently, a second pre-exposure material layer, which is in contact with the one or more first cured portions, is formed by elongating a second material; a second post-exposure material layer, which comprises one or more exposed portions, is formed by exposing the second pre-exposure material layer to light; and one or more second cured portions are caused to remain by removing one or more second unexposed portions from the second post-exposure material layer.
B33Y 30/00 - Apparatus for additive manufacturingDetails thereof or accessories therefor
B33Y 50/02 - Data acquisition or data processing for additive manufacturing for controlling or regulating additive manufacturing processes
B29C 64/106 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material
B29C 64/188 - Processes of additive manufacturing involving additional operations performed on the added layers, e.g. smoothing, grinding or thickness control
A device for the batch reactive mixing and degassing of thermosetting polymers, such as polyurethane or similar, comprising at least one hermetically sealable container (1) in which the batch of thermosetting polymers is to be placed, a rotary plate (2) on which a satellite rotary plate is rotatably mounted, the container (1) being placed on said satellite rotary plate in order to cause said container (1) to rotate and to revolve, first means for driving the rotary plate (2) and second means for driving the satellite rotary plate, and means (3) for placing the container (1) under vacuum; said device is noteworthy in that it comprises means for controlling the first means for driving the rotary plate (2) providing a speed of revolution of the container (1) and a second means for driving the satellite rotary plate providing a speed of rotation of said container (1), said control means being capable of continuously varying the speed of revolution and the speed of rotation of the container (1) independently of one another. A process for the batch reactive mixing and degassing of thermosetting polymers.
The present invention provides a transfer mechanism for a device chip. This transfer mechanism for a device chip comprises: a first substrate that has a first adhesive layer which is a transfer source of a device chip 11, and to which the device chip 11 is caused to adhere; a second substrate 10 that has a second adhesive layer 10a which is a transfer destination of the device chip 11, and to which the device chip 11 is caused to adhere; a transfer drum 21 that has a transfer adhesive layer 21a to which the device chip 11 is caused to adhere, the transfer drum 21 receiving the device chip 11 from the first substrate and transferring the device chip 11 to the second substrate 10; and an irradiation mechanism 23 that irradiates the transfer adhesive layer 21a, to which the device chip 11 is adhering, with ultraviolet light. The transfer adhesive layer 21a is configured from an ultraviolet light modification material, the adhesive force for transfer of which is decreased by the irradiation of ultraviolet light in comparison to the adhesive force for transfer thereof before the irradiation of ultraviolet light; and the adhesive force for transfer of the ultraviolet light modification material is higher than the first adhesive force of the first adhesive layer before the irradiation of ultraviolet light, while being lower than the second adhesive force of the second adhesive layer 10a after the irradiation of ultraviolet light.
H01L 21/60 - Attaching leads or other conductive members, to be used for carrying current to or from the device in operation
H01L 21/677 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components for conveying, e.g. between different work stations
A stirring and defoaming device is a stirring and defoaming device of a revolution and rotation type, wherein a vacuum unit for sucking air in each container to bring the inside of each container into a vacuum state includes sealing bodies that seal respective containers, a vacuum generation source, a suction path running toward a revolution center with each container as a starting end, passing through the revolution center to go outside the system, and reaching the vacuum generation source placed outside the system, at least part of the suction path being an independent path from the starting end in association with each container, and at least two or more vacuum measurement units, each provided in an independent path.
Provided is a container 1 for an agitation/defoaming treatment, the container 1 having a bottomed-cylindrical shape that internally accommodates a to-be-treated substance 5, and being used by an agitation/defoaming treatment device 100 that subjects the to-be-treated substance 5 to an agitation/defoaming treatment. A plurality of irregularities 2 having an irregular shape are formed on at least a portion of an internal surface, of the container 1, contacting the accommodated to-be-treated substance 5.
The present disclosure relates to techniques for performing a predetermined process on a wafer and inspecting the state of the wafer on which the predetermined process has been performed, and provides a semiconductor manufacturing device that is more convenient than before and can be implemented by means of a relatively simple configuration. The semiconductor manufacturing device comprises: a processing device for performing a predetermined process on a wafer in a processing chamber; a housing forming a transfer chamber; a transfer mechanism disposed in the transfer chamber to transfer a wafer; a plurality of load ports attached to the housing forming the transfer chamber; a transfer container detachably and hermetically attached to at least one of the plurality of load ports; and a measuring unit 35 disposed in a measuring chamber 26a. A measuring device 25 for measuring the state of the wafer on which the predetermined process has been performed is detachably and hermetically attached to a load port 10d different from the load port to which the transfer container is attached. The transfer mechanism loads the wafer unloaded from the transfer container into the processing chamber, unloads the wafer on which the predetermined process has been performed from the processing chamber, and loads the wafer into the measuring chamber 26a.
H01L 21/66 - Testing or measuring during manufacture or treatment
H01L 21/677 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components for conveying, e.g. between different work stations
20.
Apparatus for manufacturing electronic device using device chip
An apparatus includes a first substrate including a first adhesive layer, a second substrate including a second adhesive layer, a first drum that is rotatable, and a third adhesive layer located on the first drum. The first drum moves to a first location to separate device chips from the first adhesive layer of the first substrate and adheres the device chips to the third adhesive layer by rotating the first drum, and moves to a second location to separate the device chips from the third adhesive layer by rotating the first drum. The adhesive force of the first adhesive layer is less than the adhesive force of the third adhesive layer, and the adhesive force of the third adhesive layer is less than the adhesive force of the second adhesive layer.
H01L 23/00 - Details of semiconductor or other solid state devices
G09F 9/33 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements being semiconductor devices, e.g. diodes
H01L 21/67 - Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereofApparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components
The purpose of the present invention is to provide a manufacturing method for an EL display device, the method capable of forming highly reliable auxiliary wiring in a display region of the EL display device. Provided is a manufacturing method for an EL display device provided with a first electrode, a second electrode, a plurality of EL material layers, and a partition wall, and including a display region including a plurality of EL element regions, and an isolation region that isolates the plurality of EL element regions from each other by the partition wall. The manufacturing method comprises: a supply step for forming a conductive ink film a by coating a transfer region 32a on a transfer medium 32 having a cylindrical peripheral wall with conductive ink in which conductive particles are dispersed in a solvent; and a transfer step for forming auxiliary wiring to be electrically connected to the second electrode on a partition wall top surface part of the isolation region by bringing the conductive ink film a formed on the transfer region 32a of the cylindrical peripheral wall into pressure contact with the display region and transferring the conductive ink film to the partition wall top surface part while rotating the transfer medium 32 about the axis of the cylindrical peripheral wall.
G09F 9/00 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements
G09F 9/30 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements
H01L 27/32 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including components using organic materials as the active part, or using a combination of organic materials with other materials as the active part with components specially adapted for light emission, e.g. flat-panel displays using organic light-emitting diodes
H05B 33/10 - Apparatus or processes specially adapted to the manufacture of electroluminescent light sources
H05B 33/12 - Light sources with substantially two-dimensional radiating surfaces
H01L 51/50 - Solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; Processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof specially adapted for light emission, e.g. organic light emitting diodes (OLED) or polymer light emitting devices (PLED)
H05B 33/22 - Light sources with substantially two-dimensional radiating surfaces characterised by the chemical or physical composition or the arrangement of auxiliary dielectric or reflective layers
Provided is a wiring board which is highly reliable despite using a thin and easily breakable material, and which allows front and back wiring patterns provided on both surfaces of the wiring board to be connected by means of a wiring member. A wiring board B is provided with a connecting portion electrically connecting a front-surface wiring pattern 2 on a front surface of a board 1 and a back-surface wiring pattern 3 on a back surface of the board 1 across a side surface of the board 1. The connecting portion is formed of a wiring member S having a base material film 4, a connection wiring pattern 5 formed on a surface on one side of the base material film 4, and an anisotropic conductive film 6 formed to cover the connection wiring pattern 5. The wiring member S is adhesively fixed so as to cover the board 1 from a front-surface side edge of the board 1 to a back-surface side edge thereof across the side surface of the board 1, with the anisotropic conductive film 6 disposed between, in the thickness direction of the board 1, the front-surface wiring pattern 2 and the connection wiring pattern 5 and between the back-surface wiring pattern 3 and the connection wiring pattern 5.
The present invention provides image processing suitable for measuring a screen printing plate. This image processing method is provided with: an extraction reference setting step; and a region extraction step of extracting a prescribed region from an image to be processed on the basis of an extraction reference. The prescribed region is a region having a periodic or irregular shading derived from a grounding surface of an object to be imaged. The extraction reference setting step has a range selection step of selecting, in an image to be processed, an arbitrary small region including shading from a region visually recognized by an operator to be included in a prescribed region, and a hue range specifying step of specifying a range of a hue value of a pixel belonging to the arbitrary small region on the basis of data of the image to be processed described in an HSV color coordinate system. The range of the hue value specified in the hue range specifying step is set as an extraction reference. The region extraction step has a pixel specifying step of specifying a pixel in which the hue value matches the extraction reference in the image to be processed, and a region including all pixels specified in the pixel specifying step is extracted.
A device for the batch reactive mixing and degassing of thermosetting polymers, such as polyurethane or similar, comprising at least one hermetically sealable container (1) in which the batch of thermosetting polymers is to be placed, a rotary plate (2) on which a satellite rotary plate is rotatably mounted, the container (1) being placed on said satellite rotary plate in order to cause said container (1) to rotate and to revolve, first means for driving the rotary plate (2) and second means for driving the satellite rotary plate, and means (3) for placing the container (1) under vacuum; said device is noteworthy in that it comprises means for controlling the first means for driving the rotary plate (2) providing a speed of revolution of the container (1) and a second means for driving the satellite rotary plate providing a speed of rotation of said container (1), said control means being capable of continuously varying the speed of revolution and the speed of rotation of the container (1) independently of one another. A process for the batch reactive mixing and degassing of thermosetting polymers.
A state monitoring system for stirring-degassing processing that includes: a sensor unit and a computer, the sensor unit including a temperature sensor that determines a temperature of a processing target material and a first transmitter-receiver that transmits output values of the temperature sensor to the computer, the computer includes a second transmitter-receiver, an information recorder, and a processor, the second transmitter-receiver receives output values of the temperature sensor transmitted by the first transmitter-receiver. A phenomenon that may appear in output values of the temperature sensor during processing and content of post-comparison determination processing performed by the processor according to the phenomenon are associated in information that is recorded in the information recorder, and the processor compares information recorded in the information recorder and a specific phenomenon that has appeared in output values of the temperature sensor during processing, and performs post-comparison determination processing according to a result of the comparison.
In order to allow suitable management and/or control of a vacuum state, provided is a stirring and defoaming device that is a revolving and rotating type stirring and defoaming device wherein a vacuum unit for placing the interior of containers 40 in a vacuum state by suctioning air from inside the containers 40 comprises: a seal body 71 that seals the containers 40; a vacuum generation source 72; suction channels 73 that are suction channels extending to the center of revolution with each of containers 40 as a start end, coming out of the system through the center of revolution, and arriving at the vacuum generation source 72 installed outside the system, wherein at least a portion from the start end is an independent channel corresponding to the container 40; and at least two vacuum measurement units 80, 80 that are provided in each independent channel.
According to the present invention, it is possible to specify the arrangement position of a mesh yarn provided in a mesh stretched body for manufacturing a screen printing plate, and refer to the arrangement position when creating pattern data for a screen opening. This mesh position specifying device comprises: an image capturing means for capturing an image of a screen mesh; a specific processing means for specifying, on the basis of the obtained captured image, the respective arrangement positions of a plurality of the mesh yarns in the mesh stretched body, for each repeating unit in the screen mesh, and generating mesh position data described by rearranging the coordinate values of the arrangement positions specified for each repeating unit in the order along the extending direction of the mesh yarn; and an associating means for associating the mesh position data with identification information for uniquely identifying the mesh stretched body to be image-captured, wherein the specific processing means generates the mesh position data in a data format by which the arrangement positions of the plurality of mesh yarns can be substantially reproduced when creating the pattern data.
H05K 3/12 - Apparatus or processes for manufacturing printed circuits in which conductive material is applied to the insulating support in such a manner as to form the desired conductive pattern using printing techniques to apply the conductive material
A temperature-measuring device including a transmitter and a receiver. The transmitter is configured to measure the temperature of the material being contained in a container being revolved and/or rotated, and is configured to transmit data including a value of the measured temperature. The receiver is configured to receive the transmitted data. The transmitter is disposed in or on an upper lid detachably secured to the container, so that the transmitter can detect an incident light emitted from the material, and the transmitter can be revolved along with the container.
09 - Scientific and electric apparatus and instruments
Goods & Services
3D printers; additive manufacturing apparatus in the nature of 3D printers; stereo lithographic apparatus, namely, 3D printers; printing machines; printing machines for manufacturing printed circuit boards, namely, high resolution offset printers; printing machines for manufacturing electronic components, namely, high resolution offset printers; printing machines for manufacturing electronic devices, namely, high resolution offset printers; offset printers; sorting machines for chemical processing, namely, classifiers to be used for particulate objects; sorting machines for chemical processing, namely, classifiers; mixing and degassing mixing machines, namely, planetary mixers; mixing machines for mixing semiconductor materials, materials of electronic components, materials of liquid crystal displays, pharmaceuticals, cosmetics, paints, foods, adhesives, solder pastes, silver pastes and the like, other than for medical purposes; mixing machines with pulverizing function; stirring machines being mixing machines; agitating machines being mixing machines; pulverizing machines being granulating machines for chemical processing; crushing machines for industrial purposes for chemical processing; separating machines for chemical processing; mixing machines for chemical processing machines; mixing machines; manufacturing machines for liquid crystal display and light-emitting diode display devices, namely, flat panel display manufacturing machines and systems comprised of manufacturing machines for liquid crystal display and light-emitting diode display devices; printed circuit board manufacturing machines and apparatus in the nature of 3D printers; semiconductor manufacturing machines and systems comprised of semiconductor manufacturing machines; machines and machine tools for the cutting and forming of materials, namely, secondary battery manufacturing machines and systems Testing apparatus for testing semiconductors; computer-controlled testing apparatus for testing flat panel displays; instruments for measuring length, namely, machines and apparatus for measuring the length of measuring object; interferometers; scientific instruments for measuring length, measuring thickness, and counting biological colonies in the nature of colony counters
30.
SLURRY FOR PHOTOFABRICATION AND METHOD FOR MANUFACTURING PHOTOFABRICATED ARTICLE USING SAME
[Problem] To provide a slurry to be used in photofabrication for manufacturing a highly detailed three-dimensional fabricated article, and a photofabrication method in which this slurry is used. [Solution] A slurry for photofabrication can achieve both coating characteristics and at-rest shape retention characteristics by: including a photocurable resin, first inorganic particles, and second inorganic particles; the average particle diameter of the first inorganic particles being 1–5 µm; the particle diameter of the second inorganic particles being no more than 0.22 times that of the first inorganic particles; the volume ratio of the second inorganic particles to the first inorganic particles being at least 0.01; and the viscosity at shear velocities of 10 1/s and 0.01 1/s being 50 Pa·s or less and 500 Pa·s or more, respectively. By forming a pattern using laser light in a layer of this slurry, a highly detailed three-dimensional photofabricated article can be manufactured.
B28B 1/30 - Producing shaped articles from the material by applying the material on to a core, or other moulding surface to form a layer thereon
B29C 64/135 - Processes of additive manufacturing using only liquids or viscous materials, e.g. depositing a continuous bead of viscous material using layers of liquid which are selectively solidified characterised by the energy source therefor, e.g. by global irradiation combined with a mask the energy source being concentrated, e.g. scanning lasers or focused light sources
An agitation/defoaming device is provided, which can independently control revolving and rotational motion and can change a rotational direction relative to a revolving direction without a two-system rotary drive.
The apparatus includes a rotary driving source, a braking device for rotary motions; first and second rotors revolved around revolving shaft, and first and second rotational bodies and container holders pivotally supported by the first rotor. A braking force is applied to the second rotor revolving along with the first rotor, generating a rotational motion, which is transmitted to either the first or second rotational body according to the revolving direction of the first rotor. The rotational motion is then transmitted from the first or second rotational body to the container holder through the first rotational body, thereby transmitting to the object the rotational motion according to the revolving direction while revolving the object.
F16H 3/44 - Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion using gears having orbital motion
F16H 37/06 - Combinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with a plurality of driving or driven shaftsCombinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with arrangements for dividing torque between two or more intermediate shafts
A state monitoring system 1 for an agitating and degassing process performed while a container accommodating an object being processed is being caused to revolve and rotate in an agitating and degassing processing device is provided with a sensor unit 2 and an analyzing unit, wherein: the sensor unit 2 is provided with a temperature sensor 3 capable of identifying the temperature of the object being processed, and a first transmitting and receiving unit which transmits an output value of the temperature sensor 3 to the analyzing unit; the analyzing unit includes a second transmitting and receiving unit, a recording unit, and an assessing unit 14; the second transmitting and receiving unit receives the output value of the temperature sensor 3 transmitted by the first transmitting and receiving unit; the recording unit records information associating a phenomenon that may be manifested in the output value of the temperature sensor 3 during the agitating and degassing process, with the content of a post-comparison-and-determination process performed by the assessing unit 14 in accordance with the phenomenon; and the assessing unit 14 compares the information recorded in the recording unit with the specific phenomenon manifested in the output value of the temperature sensor 3 during the agitating and degassing process, and performs the post-comparison-and-determination process corresponding to the comparison result.
A photocurable composition is supplied onto an auxiliary table provided to be capable of being adjacent to a fabrication table. One of the fabrication table and the auxiliary table is moved relative to the other one of the fabrication table and the auxiliary table in an up-and-down direction. The photocurable composition that has been supplied to the auxiliary table is drawn and spread by a recoater on a fabrication surface of the fabrication table or on a cured composition layer. The photocurable composition on the fabrication surface of the fabrication table is exposed by an exposure device, so that a cured composition layer is formed.
[Problem] To provide a temperature measurement device capable of accurate, real-time measurement of the temperature of a material being processed while contained in a container, in the context of a rotational treatment process that, for example, agitates and defoams the material being processed by revolving and spinning the container. [Solution] The top part of the container is provided with a transmission unit that measures, by means of a radiation thermometer in real time and in non-contacting manner, the temperature of the material being processed during the rotational treatment. The measured temperature value is transmitted from the transmission unit and received and recorded by a reception unit installed outside the container. The recorded measured value can also be compared to pre-recorded reference data and used to determine the occurrence of an abnormality in the agitation and defoaming treatment. In addition, the measured data enables the optimization of the agitation and defoaming treatment.
[Object] To provide a method and an apparatus for manufacturing electronic devices by transferring the device chips from one substrate for producing device chips to the other substrate for a product having a large display.
[Means of Realizing the Object] A substrate having a plurality of device chips is brought into contact with a first drum including a selective adhesive region, the device chips are transferred by making the device chips be adhered to the selective adhesive layer of the first drum and separating at least part of the device chips from the substrate by rotating the first drum, then, the device chips on the first drum are made to be come into contact with the other substrate for the product, and the device chips are transferred to the substrate for the product by rotating the first drum. Additionally, the front-and-rear relation for the surfaces may be inversed by, after the device chips on the first drum are transferred to the second drum, transferring the device chips on the second drum to the substrate for the product.
H01L 23/00 - Details of semiconductor or other solid state devices
G09F 9/33 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements being semiconductor devices, e.g. diodes
This image acquisition device comprises a conveyance mechanism, an epi-lighting unit (71), a transmitted illumination unit (72), and an imaging unit (73). The conveyance mechanism conveys a tablet (9) by moving a conveyance belt (12) while the tablet (9) is suctioned and held at a suction hole (14) provided on the conveyance belt (12). The epi-illumination unit (71) emits light toward the tablet (9) from the side of the conveyance belt (12) with the surface (12a) whereon the tablet (9) is held. The transmitted illumination unit (72) emits light toward the tablet (9) from the reverse surface (12b) of the conveyance belt (12). When the imaging unit (73) captures images, both the epi-illumination unit (71) and the transmitted illumination unit (72) emit light. This makes it possible to brightly illuminate both the portion of the tablet (9) which overlays the suction hole (14) when viewed from the imaging unit (73) and the portion which does not overlay the suction hole (14). Accordingly, the tablet (9) that is light-transmissive can be clearly imaged.
A61J 3/06 - Devices or methods specially adapted for bringing pharmaceutical products into particular physical or administering forms into the form of pills, lozenges or dragees
37.
Agitation/defoaming method and agitation/defoaming device
[Problem] To provide a agitation/defoaming method and device with which both of uniformity in dispersion of object to be processed and reduction of air bubbles can be achieved with high precision.
[Solution] Provided is a agitation/defoaming method for producing orbital and spin motions of a container containing object to be processed by a device provided with orbital and spin drive motors that can independently control the velocities of the orbital and spin motions. Both defoaming and agitating treatments with high precision can be achieved by respectively performing a reverse rotation superimposition processing, wherein the rotational frequency of the spin drive motor is obtained by superimposing the first rotational frequency in a direction opposite to the direction of the orbital motion on the frequency of the orbital motion, and a same rotation superimposition processing, wherein the rotational frequency of the spin drive motor is obtained by superimposing the second rotational frequency in the same direction as the direction of the orbital motion on the frequency of the orbital motion, at least once.
[Problem] To provide a device in which, without use of an expensive dual-system rotary driving system, the rotary motions of revolution and rotation are independently controlled and the rotary direction of rotation with respect to revolution can be changed, and which has excellent stirring and defoaming characteristics. [Solution] The present invention is provided with: a rotary driving source and a rotary motion braking device; a first revolving body and a second revolving body that revolve around an axis of revolution; a first rotation body and a second rotation body that are axially supported in a rotatable manner relative to the first revolving body; and a container holder. A rotation motion is generated in such a way that the second revolving body, to which a brake force is applied by the braking device, rotates together with the first revolving body, the rotation motion is transmitted by selecting the first rotation body or the second rotation body according to the revolving direction of the first revolving body; and the rotation motion is transmitted to the container holder from the first rotation body, or transmitted to the container holder from the second rotation body through the first rotation body. Thus, a rotary motion in which rotation occurs in a rotary direction depending on the revolution direction during revolution may be applied to an object to be processed.
F16H 37/06 - Combinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with a plurality of driving or driven shaftsCombinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with arrangements for dividing torque between two or more intermediate shafts
F16H 37/08 - Combinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with a plurality of driving or driven shaftsCombinations of mechanical gearings, not provided for in groups comprising essentially only toothed or friction gearings with arrangements for dividing torque between two or more intermediate shafts with differential gearing
39.
OPTICAL SHAPING APPARATUS AND OPTICAL SHAPING METHOD
A photocurable composition is supplied on an auxiliary table provided so as to be capable of adjoining a shaping table. The shaping table or the auxiliary table is moved relative to the other in the vertical direction. The photocurable composition supplied on the auxiliary table is drawn out on the shaping surface of the shaping table or on a cured composition layer by a recoater. A cured composition layer is formed by exposure of the photocurable composition on the shaping surface of the shaping table by an exposure device.
This tablet printing device is provided with: a head (21) having a discharge surface (210) on which a plurality of ink nozzles are arranged; and a cleaning unit (23) for cleaning the discharge surface (210) of the head (21). The cleaning unit (23) is provided with: a cap (71) which covers the discharge surface (210); and a cleaning nozzle (72) and a blade (74) which are provided inside the cap. When cleaning the head (21), firstly a cleaning liquid is discharged from the cleaning nozzle (72) towards the discharge surface (210). The cleaning liquid which has adhered to the discharge surface (210) is subsequently wiped off by the blade (74). Accordingly, fine powder from tablets which has adhered to the discharge surface (210) can be efficiently removed. Furthermore, the blade (74) can also be cleaned by the cleaning liquid discharged from the cleaning nozzle (72).
A61J 3/06 - Devices or methods specially adapted for bringing pharmaceutical products into particular physical or administering forms into the form of pills, lozenges or dragees
A61J 3/00 - Devices or methods specially adapted for bringing pharmaceutical products into particular physical or administering forms
A drying unit (30) of this tablet printing device is provided with: a blower fan (81) which forms a flow of a gas; heaters (82) for heating the gas; and a plurality of blow-out ports (31) through which the heated gas is blown out towards tablets. Each of the plurality of blow-out ports (31) is provided in a position facing the conveyed tablets (9). Accordingly, the heated gas can be prevented from laterally hitting the tablets (9) being conveyed. Therefore, the gas can be made to hit the tablets forcefully, while preventing the tablets (9) being conveyed from being blown off. As a result, ink adhered to the surfaces of the tablets (9) can be dried efficiently.
F26B 21/00 - Arrangements for supplying or controlling air or gases for drying solid materials or objects
A61J 3/06 - Devices or methods specially adapted for bringing pharmaceutical products into particular physical or administering forms into the form of pills, lozenges or dragees
F26B 3/04 - Drying solid materials or objects by processes involving the application of heat by convection, i.e. heat being conveyed from a heat source to the materials or objects to be dried by a gas or vapour, e.g. air the gas or vapour circulating over, or surrounding, the materials or objects to be dried
F26B 15/00 - Machines or apparatus for drying objects with progressive movementMachines or apparatus with progressive movement for drying batches of material in compact form
42.
TRANSFER APPARATUS FOR ELECTRONIC DEVICE, AND TRANSFER METHOD FOR ELECTRONIC DEVICE
In the present invention, a calibration plate is disposed on the support surface of a table. The calibration plate has first and second alignment marks arranged next to each other in one direction and third and fourth alignment marks arranged next to each other in another direction orthogonal to the one direction. The first and second alignment marks, which move in the forward and backward directions, are imaged by a first camera. On the basis of the image, the one direction of the calibration plate is made to be parallel to the forward and backward directions. The positions of second and third cameras are adjusted on the basis of the third and fourth alignment marks. The position-adjusted second and third cameras are moved to a position below a transfer roller, and a reference line formed on the transfer roller is imaged by the second and third cameras. The orientation of the rotation axis of the transfer roller is adjusted within a plane parallel to the support surface on the basis of the images.
B41F 3/56 - Devices for adjusting cylinders relative to type-beds and setting in adjusted position
B41F 3/34 - Cylinder presses, i.e. presses essentially comprising at least one cylinder co-operating with at least one flat type-bed of special construction or for particular purposes for lithography for offset printing
B41F 33/00 - Indicating, counting, warning, control or safety devices
H05K 3/12 - Apparatus or processes for manufacturing printed circuits in which conductive material is applied to the insulating support in such a manner as to form the desired conductive pattern using printing techniques to apply the conductive material
43.
METHOD AND APPARATUS FOR MANUFACTURING ELECTRONIC DEVICE USING DEVICE CHIP
[Problem] To provide a method and an apparatus for manufacturing an electronic device by selectively transferring a device chip from a device chip manufacturing substrate to a large-area product substrate at low cost and with high arrangement accuracy. [Solution] A substrate with a plurality of device chips and a first drum with adhesive selective adhesion regions are brought into contact with each other, and, while the first drum is being rotated, at least some of the device chips on the substrate are selectively peeled off and transferred by adhesion onto the selective adhesion regions of the first drum. Thereafter, the device chips on the first drum are brought into contact with a product substrate and are transferred onto the product substrate while the first drum is being rotated. It is also possible to invert the top and bottom of an electronic device by transferring the device chips on the first drum onto a second drum and then transferring the device chips from the second drum onto a product substrate.
H01L 21/60 - Attaching leads or other conductive members, to be used for carrying current to or from the device in operation
G09F 9/33 - Indicating arrangements for variable information in which the information is built-up on a support by selection or combination of individual elements in which the desired character or characters are formed by combining individual elements being semiconductor devices, e.g. diodes
This optical shaping device is provided with a resin holding part, an optical unit, a housing, and a cleaning unit. The resin holding part is stored in the housing. The resin holding part holds a photocurable resin. The photocurable resin has a shaping surface. Clean air purified by the cleaning unit is supplied into an internal space that is in contact with the shaping surface of the photocurable resin in the housing. In this state, light is applied on the shaping surface of the photocurable resin by the optical unit. Accordingly, a three-dimensionally shaped product is produced on the shaping surface by means of stereolithography.
09 - Scientific and electric apparatus and instruments
10 - Medical apparatus and instruments
Goods & Services
3D printers; printing machines; printing machines for
manufacturing printed circuit boards; printing machines for
manufacturing electronic components; offset printing
machines; classifiers to be used for particulate objects
[chemical processing machines and apparatus]; classifiers
[chemical processing machines and apparatus]; mixing and
degassing machines, other than for medical purposes; mixing
machines for mixing semiconductor materials, materials of
electronic components, materials of liquid crystal displays,
pharmaceuticals, cosmetics, paints, foods, adhesives, solder
pastes, silver pastes and the like, other than for medical
purposes; mixing machines with pulverizing function;
stirring machines; agitating machines; pulverizing machines
[chemical processing machines and apparatus]; crushing
machines [for chemical processing]; chemical processing
machines and apparatus; mixing machines for chemical
processing machines; mixing machines; flat panel display
manufacturing machines and systems; printed circuit board
manufacturing machines and apparatus; semiconductor
manufacturing machines and systems; secondary battery
manufacturing machines and systems; machines or systems for
disposal of wastes or sewage through sewage systems in
hospitals and sanatoriums; waste shredding machines; waste
treating machines or systems; waste compacting machines and
apparatus; waste crushing machines. Downloadable maps; downloadable aerial photographs; storage
media recorded with images and texts of maps and aerial
photographs; storage media recorded with maps; storage media
recorded with aerial photographs; computer programs for map
data; computer programs; computer software; testing
apparatus for testing semiconductors; testing apparatus for
testing flat panel displays; electronic machines, apparatus
and their parts; machines and apparatus for measuring the
length of measuring object; interferometers; measuring or
testing machines and instruments; downloadable image files;
audio and video recordings; storage media recorded with
image data; electronic publications. Mixing and degassing machines for medical purposes; mixing
machines for medical purposes; medical machines and
apparatus; disposable urinals made of pulp [for medical
purposes]; cups for collecting sputum; disposable dishes
made of pulp [for medical purposes]; disposable bowls made
of pulp [for medical purposes]; disposable basins made of
pulp [for medical purposes]; urinals [for medical purposes];
bed pans; basins for medical purposes; trays for medical
purposes; bowls for medical purposes.
46.
STIRRING/DEGASSING METHOD AND STIRRING/DEGASSING DEVICE
[Problem] To provide a stirring/degassing method and device with which both uniformity in dispersion of material to be treated and reduction of bubbles can be achieved with high precision. [Solution] Provided is a stirring/degassing method for producing orbital motion and rotational motion of a container accommodating material to be processed by a device provided with an orbital motion drive motor and a rotational drive motor that can independently control rotational speed for orbital motion and rotational speed for rotation, wherein reverse rotation superimposition processing with the rotational frequency of the rotational drive motor being set by superimposing a first rotational frequency on the rotational frequency of orbital motion in a direction opposite to the orbital motion, and same rotation superimposition processing with the rotational frequency of the rotational drive motor being set by superimposing a second rotational frequency on the rotational frequency of the orbital motion in the same direction as the orbital motion, are implemented at least once. Thus, it is possible to carry out both degassing treatment and stirring treatment with high precision.
A revolution/rotation device comprises: a rotating section 2 configured to be rotatable about a revolution axis X1 and provided with a rotation axis X2; a container holder 3 for holding a container 4 capable of containing an object to be treated, the container holder 3 being installed on the rotating section 2 so as to be rotatable about the rotation axis X2 and so as to revolve as the rotating section 2 rotates about the revolution axis X1; and a rotation motor 18 mounted to the rotating section 2 and rotating the container holder 3. The rotation axis X3 of the rotation motor 18 and the revolution axis X1 are coaxially aligned. The revolution/rotation device also comprises a conversion mechanism 24 for converting the torque of the rotation motor 18 into the rotational force of the container holder 3.
Mixing and degassing machines, other than for medical
purposes; mixing machines for mixing semiconductor
materials, materials of electronic components, materials of
liquid crystal displays, pharmaceuticals, cosmetics, paints,
foods, adhesives, solder pastes, silver pastes and the like,
other than for medical purposes; mixing machines with
pulverizing function; stirring machines; agitating machines;
pulverizing machines [chemical processing machines and
apparatus]; crushing machines [for chemical processing];
chemical processing machines and apparatus; food mixing
machines for commercial use; mixing machines for chemical
processing machines; mixing machines. Mixing and degassing machines for medical purposes; mixing
machines for medical purposes; medical machines and
apparatus.
A stirring/defoaming apparatus provided with: a revolving rotor; at least one rotating and revolving container capable of accommodating a substance to be processed; a balance weight configured so as to be capable of moving toward and away from the revolution axis; an X-axis acceleration detection unit disposed so that the detection direction is oriented toward the X-axis direction, among horizontal directions; a Y-axis acceleration detection unit disposed so that the detection direction is oriented toward a Y-axis direction orthogonal to the X-axis direction, among horizontal directions; a Z-axis acceleration detection unit disposed so that the detection direction is oriented toward a Z-axis direction that is the vertical direction; and a position-displacement determination unit for determining the position displacement in relation to the revolution axis of a center-of-gravity balance position of a revolving rotating body that is the revolving portion including the rotor, on the basis of the detection results of the X-axis acceleration detection unit, the Y-axis acceleration detection unit, and the Z-axis acceleration detection unit.
Disclosed is an agitation/defoaming device that has a simple configuration and can reduce the size of vibrations resulting from fluctuations in the position of the center of gravity of a container. The disclosed agitation/defoaming device is provided with a container that contains a material to be treated and can rotate and/or revolve. The agitation/defoaming device is also provided with a balance-adjustment device whereby the center of gravity of the container moves due to centrifugal force resulting from revolution of the container. The balance-adjustment device has a moving body which is biased radially inwards and which moves outwards against said bias as a result of the centrifugal force due to the revolution of the container.
A stirring and defoaming device and a stirring and defoaming method which can reliably stir and defoam materials to be processed which are contained in containers. The stirring and defoaming device comprises: a table (2) which is configured so as to be rotatable about a revolution axis (C1) and has rotation axes (C2); and containers (3) which are configured so as to be able to contain materials to be processed, the containers (3) being provided to the table (2) such that each of the container (3) can rotated about the associated rotation axis (C2) and that the containers (3) are revolved by rotation of the table (2) about the revolution axis (C1). The rotation axes (C2) are located at twisted positions relative to the revolution axis (C1).
