A throttling device which can suppress noise and a refrigeration cycle system are provided. This throttling device (10) is provided with: a valve seat member (2) which comprises a valve port (21); a needle valve (4) which makes it possible to change the opening degree of the valve port (21); and a cylindrical guide member (3) which guides forward and backward movement of the needle valve (4). On the needle valve (4) and the guide member (3), sliding surfaces (34, 46) are formed which face one another across a predetermined gap and which can slide against one another. The gap functions as an intermediate flow path (45) allowing a fluid to pass from the valve port (21) towards the secondary side, and on the sliding surface (46) of the needle valve (4), a concave groove (47) is formed which is a flow path expanded portion that is recessed in the direction away from the sliding surface (34) of the guide member (3) and that expands the width dimension of the intermediate flow path (45).
F16K 17/30 - Soupapes ou clapets limiteurs de débit fonctionnant par différence de pression entre deux points de l'écoulement et agissant directement sur l'élément d'obturation dans un sens uniquement sous l'action d'un ressort
F16K 1/32 - Soupapes ou clapets, c. à d. dispositifs obturateurs dont l'élément de fermeture possède au moins une composante du mouvement d'ouverture ou de fermeture perpendiculaire à la surface d'obturation - Détails
F16K 17/34 - Soupapes ou clapets limiteurs de débit dans lesquels l'énergie provenant du courant du fluide actionne le mécanisme de fermeture
F16K 47/02 - Moyens incorporés aux soupapes pour absorber l'énergie d'un fluide pour empêcher les coups de bélier ou le bruit
F16K 47/04 - Moyens incorporés aux soupapes pour absorber l'énergie d'un fluide pour diminuer la pression, l'organe régulateur étant incorporé dans l'élément de fermeture
F25B 1/00 - Machines, installations ou systèmes à compression à cycle irréversible
In this throttling device (10) which reduces the pressure of the refrigerant condensed by the condenser in a refrigeration cycle and feeds said refrigerant to an evaporator, locking of a needle valve (4) due to foreign matter is prevented. A cylindrical main body case (1) configures a primary chamber (11) connected to the condenser and a secondary chamber (12) connected to the evaporator, and a valve seat member (2), in which a valve port (21) is formed, and a cylindrical guide member (3), which is integral with said valve seat member (2), are provided in the cylindrical main body case (1). In the guide member (3), a coil spring (6) is provided which biases towards the needle valve (4) and the valve port (21). A guide portion (42a) is provided in an insertion portion (42) of the needle valve (4). The guide portion (42a) and a cylindrical guide surface (31a) of the guide member (3) are brought into line contact with one another to guide the needle valve (4). Multiple sliding parts (S), which engage in said line contact, are provided, and foreign matter is flushed out with the areas between adjacent sliding parts (S) acting as introduction paths (45).
F16K 17/30 - Soupapes ou clapets limiteurs de débit fonctionnant par différence de pression entre deux points de l'écoulement et agissant directement sur l'élément d'obturation dans un sens uniquement sous l'action d'un ressort
In this throttling device (10) which reduces the pressure of the refrigerant condensed by the condenser in a refrigeration cycle and feeds said refrigerant to an evaporator, hunting of a needle valve (4) is prevented and hysteresis in differential pressure/flow characteristics in the high-pressure region are reduced. A cylindrical main body case (1) configures a primary chamber (11) connected to the condenser and a secondary chamber (12) connected to the evaporator, and a valve seat member (2), in which a valve port (21) is formed, and a cylindrical guide member (3), which is integral with said valve seat member (2), are provided in the cylindrical main body case (1). In the guide member (3), a coil spring (7) is provided which biases towards the needle valve (4) and the valve port (21). A blade member (5) is provided on a boss portion (43) of the needle valve (4). A blade (51) of the blade member (5) is brought into contact with a cylindrical guide surface (31a) of the guide member (3) to apply sliding resistance. The blade (52) is displaced by the fluid pressure of the refrigerant flowing from introduction paths (45) to a back pressure chamber (44), decreasing the sliding resistance.
F16K 17/30 - Soupapes ou clapets limiteurs de débit fonctionnant par différence de pression entre deux points de l'écoulement et agissant directement sur l'élément d'obturation dans un sens uniquement sous l'action d'un ressort
F16K 47/02 - Moyens incorporés aux soupapes pour absorber l'énergie d'un fluide pour empêcher les coups de bélier ou le bruit
NATIONAL UNIVERSITY CORPORATION SHIZUOKA UNIVERSITY (Japon)
KABUSHIKI KAISHA SAGINOMIYA SEISAKUSHO (Japon)
Inventeur(s)
Hashiguchi, Gen
Nishimori, Yuki
Arioka, Shinichi
Suzuki, Masato
Ishibashi, Kazunori
Abrégé
This electret element has an electret layer including silicon oxide, and an aluminum oxide protective layer deposited on the electret layer by means of an atomic layer deposition method.
[Problem] To provide a solenoid valve drive control device that can conserve energy and that can suppress noise generated by inrush current by way of eliminating inrush current to stray capacitance of the coil and accumulating energy in a coil. [Solution] A solenoid valve drive control device comprises: a blocking mode in which current to a solenoid 66 is blocked by a switching means 68 when the current flowing to the solenoid 66 detected by a current detecting means 78 reaches a prescribed set current value Ia after current supply to the solenoid 66 is started at time of a zero-cross by the switching means 68 by way of the control of a zero-cross timing generating means 72; and a holding mode that is set so that the current flowing into the solenoid 66 is equal to or greater than a prescribed holding current value Ib by sending a holding current to the solenoid 66 through a snubber circuit 70 during the interval until the time of the next zero crossing after the current supply to the solenoid 66 is blocked by the switching means 68.
F16K 31/06 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un aimant
H01F 7/18 - Circuits en vue d'obtenir des caractéristiques de fonctionnement souhaitées, p.ex. pour un fonctionnement lent, pour l'excitation successive des enroulements, pour l'excitation à grande vitesse des enroulements
6.
STRUCTURE FOR AFFIXING DIAPHRAGM TO DRIVE SHAFT, AND ELECTROMAGNETIC CONTROL VALVE
Provided is an electromagnetic control valve in which force acting on a valve body (31) is cancelled by the use of a diaphragm (4) and by means of differential pressure, wherein the diaphragm (4) has improved durability and improved resistance to pressure. The diaphragm (4) is constituted by base fabric (4A) and a rubber layer (4B), and a drive shaft connection hole (42a) through which a drive shaft (diaphragm fitting section (324)) is passed is provided inside the inner bead section (42) of the diaphragm (4). The diameter φA' of the drive shaft connection hole (42a) is matched to the diameter of the drive shaft (diaphragm fitting section (324)) which is to be mounted in the drive shaft connection hole (42a). A thin-walled disk section (44) is provided inside the inner bead section (42), and an expandable-diameter hole (44a) is formed at the center of the disk section (44). The expandable-diameter hole (44a) and the disk section (44) are pushed and expanded to form a stretched portion (44A)(Fig. 6(C), (D)), and the stretched portion (44A) is received in a receiving groove (324b) in the drive shaft (diaphragm fitting section (324)). The diameter φA of the drive shaft, the diameter φB of the expandable-diameter hole, and the ratio C of elongation of the base fabric (4A) are set so as to satisfy the relationship of 0.7 ≤ A/(B×C) ≤ 3.0.
F16J 15/52 - Joints d'étanchéité entre organes mobiles l'un par rapport à l'autre, par étanchéité sans surfaces mobiles l'une par rapport à l'autre, p.ex. des garnitures étanches aux fluides pour transmettre un mouvement au travers d'une paroi par soufflets ou diaphragmes d'étanchéité
F16K 7/12 - Dispositifs d'obturation à diaphragme, p.ex. dont un élément est déformé, sans être déplacé entièrement, pour fermer l'ouverture à diaphragme plat, en forme d'assiette ou en forme de bol
F16K 7/16 - Dispositifs d'obturation à diaphragme, p.ex. dont un élément est déformé, sans être déplacé entièrement, pour fermer l'ouverture à diaphragme plat, en forme d'assiette ou en forme de bol disposé pour être déformé contre un siège plat le diaphragme étant actionné mécaniquement, p.ex. par une tige filetée ou par came
F16K 7/17 - Dispositifs d'obturation à diaphragme, p.ex. dont un élément est déformé, sans être déplacé entièrement, pour fermer l'ouverture à diaphragme plat, en forme d'assiette ou en forme de bol disposé pour être déformé contre un siège plat le diaphragme étant actionné par pression d'un fluide
F16K 31/06 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un aimant
[Problem] To provide, for the purpose of measuring large flow rates, a flow sensor that has reduced pressure loss compared to a conventional pressure sensor even if a flow rate increases significantly, is not subjected to a high load, has a rotary blade member for flow rate measurement having a bearing not subjected to abrasive wear, makes accurate flowmeter measurement possible, and has a long product lifetime. [Solution] A flow sensor (10) for measuring the flow rate of a fluid, said flow sensor (10) being provided with a flow sensor pipe body (12) through which the fluid flows, a flow sensor body (24) disposed in the flow sensor pipe body (12) in the direction of the flow of the fluid, and a bypass flow path (62) disposed in the flow sensor pipe body (12) in the direction of the flow of the fluid.
G01F 1/115 - Mesure du débit volumétrique ou du débit massique d'un fluide ou d'un matériau solide fluent, dans laquelle le fluide passe à travers un compteur par un écoulement continu en utilisant des effets mécaniques en utilisant des aubes tournantes avec admission axiale avec accouplement magnétique ou électromagnétique au dispositif indicateur
A throttle device (10) for decompressing a coolant cooled by a condenser in a refrigeration cycle, and delivering said coolant to an evaporator, wherein the valve opening position of a needle valve (4) is controlled according to the condensing pressure. The interior of a cylindrical body case (1) which configures a primary chamber (11) connected to the condenser and a secondary chamber (12) connected to the evaporator is provided with a valve seat member (2) in which a valve port (21) is formed, and a cylindrical guide member (3) which is integral with the valve seat member (2). The interior of the guide member (3) is provided with a coil spring (6) for biasing the needle valve (4) to the valve-port (21) side. The guide member (3) guides the needle valve (4) along an axial line (L), and adjusts the aperture of the valve port (21). The gap between the guide member (3) and the body case (1) is configured as a body-side channel (13) for delivering the coolant from the valve port (21) to the secondary chamber (12). The needle valve (4) rear space inside the guide member (3) is configured as an intermediate pressure chamber (44). An intermediate pressure introduction channel (45) introduces coolant from the valve port (21) into the intermediate pressure chamber (44).
F16K 17/30 - Soupapes ou clapets limiteurs de débit fonctionnant par différence de pression entre deux points de l'écoulement et agissant directement sur l'élément d'obturation dans un sens uniquement sous l'action d'un ressort
F16K 17/34 - Soupapes ou clapets limiteurs de débit dans lesquels l'énergie provenant du courant du fluide actionne le mécanisme de fermeture
A throttle device (10) for decompressing a coolant cooled by a condenser in a refrigeration cycle, and delivering said coolant to an evaporator, wherein it is possible to accurately set a minimum gap between a needle valve (4) and a valve port (21). The interior of a cylindrical body case (1) which configures a primary chamber (11) connected to the condenser and a secondary chamber (12) connected to the evaporator is provided with a valve seat member (2) in which the valve port (21) is formed, and a cylindrical guide member (3) which is integral with the valve seat member (2). The interior of the guide member (3) is provided with a coil spring (6) for biasing the needle valve (4) to the valve-port (21) side. A needle section (41) of the needle valve (4) projects from the valve port (21) toward the primary-chamber (11) side. A tip end section (41a) of the needle section (41) contacts a stopper member, and as a result, the position of the tip end section (41a) is set. The position of the stopper member (7) in the axial line (L) direction is adjusted by the amount of screwing relative to the valve seat member (2).
F16K 17/30 - Soupapes ou clapets limiteurs de débit fonctionnant par différence de pression entre deux points de l'écoulement et agissant directement sur l'élément d'obturation dans un sens uniquement sous l'action d'un ressort
A drainage pump which has a pump rotor (12), the pump rotor (12) being configured by including: a plurality of tandem protrusion pieces (20ai) that constitute an agitator body for applying centrifugal force to fluid; protrusion pieces (20bi); an annular outer wall (12PW) that surrounds the periphery of the plurality of protrusion pieces (20ai) adjacent thereto; and a truncated cone-shaped supporting plate (12A) integrally formed with the lower ends of the protrusion pieces (20ai) and lower ends of the outer wall (12PW) and the protrusion pieces (20bi), the supporting plate (12A) having a lower end with a shaft portion (12B) inserted into a suction opening (10a).
In a pressure-balancing electromagnetic control valve in which the degree of opening of the valve body (31) is proportionally changed by balancing the electromagnetic force of an electromagnetic drive section (5) and the spring force of an adjustment spring (83) and canceling the effects of the difference between the pressure of a first port (11) and the pressure of a second port (21) on the valve body (31), the present invention reduces the length of the valve housing (1) and accurately controls the degree of valve opening by eliminating the effect of the dynamic pressure of fluid in the second port on the plunger of the electromagnetic drive section. The electromagnetic drive section (5), adjustment spring (83) (setup adjustment section (8)), pressure equalization chamber (13) and diaphragm (4) (pressure-sensing section) are provided on the axial line (L) of the valve port (22) on the side of the valve body (31) that is opposite to the valve port (22). A cover (6) through which a connection rod (323) is inserted is provided between the pressure equalization chamber (13) and the plunger (53). The flow of fluid from the pressure equalization chamber (13) to the plunger (53)-side is constricted (controlled) by the gap between the insertion hole (6a) of the cover (6) and the connection rod (323).
F16K 31/06 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un aimant
F16K 47/04 - Moyens incorporés aux soupapes pour absorber l'énergie d'un fluide pour diminuer la pression, l'organe régulateur étant incorporé dans l'élément de fermeture
A fluid control valve which is to be connected to a wet gas flow path and which can control the flow rate of wet gas, being provided with: an introduction passage for introducing wet gas into the fluid control valve; a filter having a mesh for removing foreign matter contained in the wet gas flowing in the introduction passage; a discharge passage which has a valve port disposed in a section upper than the introduction passage and through which the wet gas that has passed through the filter is discharged from the fluid control valve via the valve port; and a valve portion in which the opening and closing of the valve port is conducted by a valving element. In this fluid control valve, the filter is disposed in the lowermost part of the introduction passage.
H01M 8/04 - Dispositions auxiliaires, p.ex. pour la commande de la pression ou pour la circulation des fluides
F16K 51/00 - Autres détails non particuliers aux types de soupapes ou clapets ou autres appareils d'obturation
F16T 1/00 - Purgeurs d'eau de condensation ou appareils similaires pour expulser un liquide hors de réservoirs contenant principalement des gaz ou des vapeurs, p.ex. conduits de gaz, conduits de vapeur, réservoirs
H01M 8/10 - PROCÉDÉS OU MOYENS POUR LA CONVERSION DIRECTE DE L'ÉNERGIE CHIMIQUE EN ÉNERGIE ÉLECTRIQUE, p.ex. BATTERIES Éléments à combustible; Leur fabrication Éléments à combustible avec électrolytes solides
A vibration electrical power generation element (1) is provided with a fixed electrode (11), a movable electrode (12) that is arranged opposite the fixed electrode (11) and is capable of moving relative to the fixed electrode (11), and an ionic liquid (13) provided so as to be interposed between the mutually opposed fixed electrode (11) and movable electrode (12). The motion of the movable electrode (12) due to an external vibration changes the area of an electric double layer (16a) and/or an electric double layer (16b), the electric double layer (16a) being formed so as to sandwich the interface of the fixed electrode (11) and the ionic liquid (13), and the electric double layer (16b) being formed so as to sandwich the interface of the movable electrode (12) and the ionic liquid (13).
Provided is a caulk structure for which caulking is easy, for which the generation of wrinkles can be prevented, and which excels in pressure resistance. The caulk structure includes at least a member to be caulked for which airtightness with respect to the surrounding environment is required, and a caulked member configured so that the member to be caulked is held by caulking. The caulked member includes an annular side-wall that surrounds the member to be caulked, and the annular side-wall has grooves formed therein.
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
F16B 4/00 - Assemblage par retrait, p.ex. en portant les pièces à assembler à des températures différentes; Montage à force; Attaches à serrage par friction non largables
F16B 5/00 - Jonction de feuilles ou de plaques soit entre elles soit à des bandes ou barres parallèles à elles
Provided is a fluid-related function device capable of inhibiting deformation of a case component or a connective member which may occur due to expansion of a fluid accumulated in a space for trapping sputter during resistance welding. A pressure switch (1) has a space (β) for trapping sputter produced during projection welding, the space being provided between a joint (10) and a cap member (20). A communicating passage (65) communicates the interior and the exterior of the space (β). The communicating passage (65) is formed so as to allow passage of a fluid while restricting passage of the sputter.
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
B21D 39/00 - Utilisation de procédés permettant d'assembler des objets ou des parties d'objets, p.ex. revêtement par des tôles, autrement que par placage; Dispositifs de mandrinage des tubes
B23K 11/00 - Soudage par résistance; Sectionnement par chauffage par résistance
The solenoid coil assembly of a solenoid valve is provided with: a coil section (20) located within a bobbin (21) disposed on the outer periphery of the circular cylindrical section (26) of a valve body section (10); an attractor (24) for closing one end of the circular cylindrical section (26); and a casing (16) for covering and housing the coil section (20) and the resinous bobbin (21). An O-ring (30) seals that gap between the outer periphery of the circular cylindrical section (26) of the valve body section (10) and the inner periphery of the circular cylinder section (22A) of a lower plate (22).
This pressure sensor is provided with: a fastening part; a ring-shaped oscillator supported on the fastening part by a plurality of support beams; a plurality of electrodes situated on the fastening part, and arranged at gaps in the oscillation direction of the ring-shaped oscillator; and an electret film formed on either one of the mutually facing surfaces of the ring-shaped oscillator and the electrodes.
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
18.
VIBRATING DEVICE AND A SIMULATOR VIBRATION SYSTEM COMPRISING SAME
A slide duct device, which is attached to each actuator (38A, 38B) of each vibrating device, is configured to have a cableveyor (42A) in which a wiring/piping material group (WH) is inserted, a guidance duct (40A), and a slide rail unit (SLU) that slidably supports the guidance duct (40A) and is provided with, on an oscillating base (12) that is connected to the actuators (38A, 38B), a wiring/piping material aligning mechanism (50) that aligns, without damaging, the wiring/piping material group (WH) that passes through the guidance duct (40A).
B06B 1/12 - Procédés ou appareils pour produire des vibrations mécaniques de fréquence infrasonore, sonore ou ultrasonore utilisant l'énergie mécanique fonctionnant avec des systèmes impliquant des masses en mouvement alternatif
G09B 9/04 - Simulateurs pour l'enseignement ou l'entraînement pour l'enseignement de la conduite des véhicules ou autres moyens de transport pour l'enseignement de la conduite des véhicules terrestres
19.
ACTUATOR, SHUTTER DEVICE, FLUID CONTROL DEVICE, SWITCH, AND TWO-DIMENSIONAL SCANNING SENSOR DEVICE
NATIONAL UNIVERSITY CORPORATION SHIZUOKA UNIVERSITY (Japon)
OMRON CORPORATION (Japon)
KABUSHIKI KAISHA SAGINOMIYA SEISAKUSHO (Japon)
Inventeur(s)
Suzuki, Masato
Mori, Akito
Hashiguchi, Gen
Sugiyama, Tatsuhiko
Imamoto, Hiroshi
Oba, Masatoshi
Mitsuya, Hiroyuki
Ashizawa, Hisayuki
Ishibashi, Kazunori
Abrégé
An actuator provided with an electrostatic driving mechanism provided with a fixed electrode and a movable electrode, a first movable part driven by the electrostatic driving mechanism, a first elastic support part for elastically supporting the first movable part, an electret formed on the fixed electrode and/or the movable electrode, and a drive controller for controlling the application of voltage to the electrostatic driving mechanism. The actuator is set with a plurality of stable states, in which the first movable part is positioned at a stable position at which the electrostatic force caused by the electret and the elastic force from the first elastic support part are balanced or at a stable position set near the stable position described above. Applying a voltage to the electrostatic driving mechanism makes it possible to move the first movable part from any stable position to another stable position.
Provided is a fluid control valve equipped with an electromagnetic coil configured so as to be positioned easily and such that the position can be changed easily; also provided is a method for securing the valve main body and an electromagnetic coil unit in the fluid control valve. The fluid control valve is equipped at least with: a valve main body, which has a cylindrical outer shape and is connected to two or more connectors through which a fluid flows in and out, and which controls the flow of the fluid by driving an embedded valve member; and an electromagnetic coil, which is mounted on the valve main body in a detachable manner, and drives the valve member. One of the two or more connectors is connected to the cylindrical valve main body so as to be orthogonal to the axis of the valve main body. The electromagnetic coil is wound on a bobbin having a cylindrical body having an insertion hole, which extends in the vertical direction and in which the valve main body is inserted. In addition, one or more notches, which open in the opposite direction from the direction in which the valve body is inserted, are formed in the cylindrical body. When the valve body is inserted into the insertion hole of the cylindrical body of the bobbin, the notches in the cylindrical body engage one of the connectors, thereby positioning the electromagnetic coil.
The purpose of the present invention is to shorten the length of a valve housing (1), reduce pressure loss in a second port (21), and prevent oscillation of a valve member (3') in a balanced-pressure solenoid-controlled valve for canceling the effect of a pressure difference between a first port (11) and the second port (21) on a valve body (31), and proportionally varying the opening degree of the valve body (31). An electromagnetic drive part (5), an adjusting spring (83) (a setting adjustment part (8)), a pressure-equalizing chamber (13), and a diaphragm (4) (depressurizing part) are provided along an axis line L of a valve port (22) on the side of the valve body (31) opposite from the valve port (22). Electrical conduction between the valve port (22) and the pressure-equalizing chamber (13) is established by the valve body (31) and the opening hole (31a), longitudinal passage (32a), and transverse passage (32b) (pressure-equalizing passage) of the valve member (3). The valve port (22) and the second port (21) have the same axis. A tapered surface (33d) is formed on the lower end of a valve body (33), and the spherical sliding surface (14b) of a spring-bearing member (14) is brought in contact with the tapered surface (33d) by a compression coil spring (15).
Provided is a valve device having a configuration which enables a pipe member to be more easily joined by laser welding to the peripheral wall of a cylindrically shaped valve housing. A solenoid valve (1) is configured in such a manner that the peripheral wall (12) of the plunger tube (10) thereof has a single flat surface portion (13) in which a through-hole (14) is formed, the through-hole (14) connecting the inside and outside of the plunger tube (10) and allowing one end of a first joint (81) to be fitted therein. The first joint (81) is joined by laser welding to the flat surface portion (13) while the one end of the first joint (81) is fitted in the through-hole (14) corresponding to the one end.
F16K 27/00 - Structures des logements; Matériaux utilisés à cet effet
F16L 41/08 - Raccordements des tuyaux aux parois ou à d'autres tuyaux, dans lesquels l'axe du tuyau est perpendiculaire au plan de la paroi ou à l'axe de l'autre tuyau
Provided is a rotary valve device that can suppress the force for pressing a valve member against a valve seat surface. In a two-way valve (1), the cylindrical section (31) of a valve member (30) has a small-diameter cylindrical portion (31a), a large-diameter cylindrical portion (31b), and a cylindrical portion step surface (31c) formed between the outer peripheral surface (31a1) of the small-diameter cylindrical portion (31a) and the outer peripheral surface (31b1) of the large-diameter cylindrical portion (31b). Also, a valve main body (10) has a valve member support section (15) provided with: a small-diameter hole section (15a) to which the small-diameter cylindrical portion (31a) can rotatably fit; a large-diameter hole section (15b) to which the large-diameter cylindrical portion (31b) can rotatably fit; and a support section step surface (15c) formed between the inner peripheral surface (15a1) of the small-diameter hole section (15a) and the inner peripheral surface (15b1) of the large-diameter hole section (15b). Also, an annular seal ring (38) is provided in the seal space (R) encircled by the outer peripheral surface (31a1) of the small-diameter cylindrical portion, the cylindrical portion step surface (31c), the inner peripheral surface (15b1) of the valve large-diameter hole section, and the support section step surface (15c).
F16K 11/074 - Soupapes ou clapets à voies multiples, p.ex. clapets mélangeurs; Raccords de tuyauteries comportant de tels clapets ou soupapes; Aménagement d'obturateurs et de voies d'écoulement spécialement conçu pour mélanger les fluides dont toutes les faces d'obturation se déplacent comme un tout comportant uniquement des tiroirs à éléments de fermeture articulés à pivot à faces d'obturation planes
F16K 3/06 - Robinets-vannes ou tiroirs, c. à d. dispositifs obturateurs dont l'élément de fermeture glisse le long d'un siège pour l'ouverture ou la fermeture à faces d'obturation planes; Garnitures d'étanchéité à cet effet avec éléments de fermeture articulés à pivot en forme de plaques disposées entre l'alimentation et l'évacuation
F16K 31/04 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un moteur
F16K 31/53 - Moyens mécaniques d'actionnement à engrenage
Provided are: a valve device that can effectively secure connection strength at the location of connection by means of welding a copper member and a stainless steel member; and a method for producing the valve device. A motor-operated valve (1) is produced by means of a production method including a welding step such that: a first connector (17) is inserted into a first interconnection hole (11A) that is formed at a valve housing (11) and that interconnects the inside and outside of the valve housing (11), and a second connector (18) is inserted in a second interconnection hole (11B); tube members (55, 56) comprising nickel are sandwiched between the valve housing (11) and the first connector (17) and second connector (18); and laser welding is performed along the peripheral direction of the first interconnection hole (11A) and the second interconnection hole (11B) in a manner so as to form a first welded section (51) and second welded section (52) resulting from stainless steel, copper, and nickel each being melted and then solidified between the valve housing (11) and the first connector (17) and second connector (18).
Provided is a pressure detection unit in which waterproof properties can be enhanced. In a pressure sensor (10), an enclosing resin part (68) is joined to an outside surface of a stainless steel, aluminum, or nickel element body (18) so as to surround a plurality of lead pins (34). In the pressure sensor (10), an annular surface-roughening part (7) formed by laser irradiation and disposed so as to partition an external peripheral edge (68a) and an internal peripheral edge (68b) on the outside surface of the element body (18) in the enclosing resin part (68) is provided at the location where the enclosing resin part (68) is joined on a top end surface (18a) of the element body (18).
In a refrigerant circuit component such as a pressure-sensing device (pressure switch, pressure sensor, etc.) or valve device, the present invention projection-welds a connector (1) to a cap member (2) and prevents intrusion of spatter into the refrigerant circuit. An A-cylinder section (1a) in which an inside hole (1A) of the connector (1) is open is inserted inside an inside hole (2A) formed in the center of the cap member (2). The area between the A-cylinder section (1a) and a projection (11d) of the connector (1) is called a spatter generation space (β). The projection (11d) of the connector (1) is abutted against the cap member (2) and projection-welded to form a weld zone (α). The open end (1A1) of the inside hole (1A) of the A-cylinder section (1a) is crimped to pressure-weld the open end (1A1) to the open edge (2A1) of the inside hole (2A) of the cap member (2). Spatter is sealed inside the spatter generation space (β). It is also possible to remove a portion of the surface layer to form structures from which spatter has been removed by machining areas in which spatter has been generated and is adhering.
B21D 39/00 - Utilisation de procédés permettant d'assembler des objets ou des parties d'objets, p.ex. revêtement par des tôles, autrement que par placage; Dispositifs de mandrinage des tubes
B23K 11/00 - Soudage par résistance; Sectionnement par chauffage par résistance
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
G01L 19/00 - MESURE DES FORCES, DES CONTRAINTES, DES COUPLES, DU TRAVAIL, DE LA PUISSANCE MÉCANIQUE, DU RENDEMENT MÉCANIQUE OU DE LA PRESSION DES FLUIDES - Détails ou accessoires des appareils pour la mesure de la pression permanente ou quasi permanente d'un milieu fluent dans la mesure où ces détails ou accessoires ne sont pas particuliers à des types particuliers de manomètres
(Problem) To provide a test device that has a light platform weight, high rigidity, is able to achieve stable operation with a lightweight base, and is capable of testing and simulations up to a high frequency in a small space and at a low motive force. (Solution) The present invention is provided with: a platform (18) that is coupled onto a base plate (14) by means of a motion coupling mechanism (16) and that is provided with a driven unit (30); and a magnetic attachment device (40) that is disposed in a manner so as to oppose a sliding floor (12) at the bottom surface of the base plate (14) and that can alter the magnetic attachment force with respect to the sliding floor (12). The configuration is such that in an operating state such that the air pressure of an air bearing (34) is high, the state of the magnetic attachment force of the magnetic attachment device (40) being strong with respect to the sliding floor (12) results, and in a non-operating state such that the air pressure of the air bearing (34) is low, the state of the magnetic attachment force of the magnetic attachment device (40) being weak with respect to the sliding floor (12) results.
G09B 9/04 - Simulateurs pour l'enseignement ou l'entraînement pour l'enseignement de la conduite des véhicules ou autres moyens de transport pour l'enseignement de la conduite des véhicules terrestres
G09B 9/02 - Simulateurs pour l'enseignement ou l'entraînement pour l'enseignement de la conduite des véhicules ou autres moyens de transport
F16M 1/00 - Châssis, carters ou carcasses pour moteurs, machines ou appareils; Châssis servant de bâtis de machines
F16M 13/00 - Autres supports ou appuis pour positionner les appareils ou les objets; Moyens pour maintenir en position les appareils ou objets tenus à la main
A fuel cell system is equipped with a fuel cell that is supplied with an anode gas and a cathode gas and generates electric power. The fuel cell system comprises: an anode off-gas flow path through which anode off-gas discharged from the fuel cell flows; a purge valve provided in the anode off-gas flow path; and a purge control unit that performs a purge stop control for opening and closing the purge valve a predetermined number of times when the fuel cell stops a power generation operation.
H01M 8/04 - Dispositions auxiliaires, p.ex. pour la commande de la pression ou pour la circulation des fluides
H01M 8/06 - Combinaison d’éléments à combustible avec des moyens de production de réactifs ou pour le traitement de résidus
H01M 8/10 - PROCÉDÉS OU MOYENS POUR LA CONVERSION DIRECTE DE L'ÉNERGIE CHIMIQUE EN ÉNERGIE ÉLECTRIQUE, p.ex. BATTERIES Éléments à combustible; Leur fabrication Éléments à combustible avec électrolytes solides
30.
CONTACT STRUCTURE OF SWITCH AND PRESSURE SWITCH USING SAME
[Problem] To provide a contact structure for a switch capable of increasing the contact region, suppressing conduction failure, and improving the operational reliability of the switch by configuring the contact points between the contacts as linear contacts. [Solution] A contact structure for a switch having a pair of contacts opposite each other to open and close the switch by the contacts coming in contact with or separating from each other, wherein the contact surface of one contact is formed into a concave surface provided with projections and recesses while the contact surface of the other contact is formed into a rounded surface, and the projections of the one contact and the rounded surface of the other contact are configured to come in contact with each other.
H01H 1/06 - Contacts caractérisés par la forme ou la structure de la surface de contact, p.ex. striée
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
31.
METHOD FOR SUPPRESSING GENERATION OF TIN WHISKERS DUE TO EXTERNAL STRESS, AND PRESSURE SWITCH OBTAINED BY USING SAID METHOD
[Problem] To provide a method for suppressing the generation of tin whiskers due to external stress and a pressure switch obtained by using the method, the method making it possible to reliably and easily suppress the generation of tin whiskers due to external stress occurring on a tin-plated component press-fitted in a plastic housing. [Solution] The problem is resolved by a method for suppressing the generation of tin whiskers due to external stress, the method including a step for press-fitting a plurality of terminals having a tin-plated dowel part in a plastic housing, a step for crimping the press-fitted terminals, and step for thermally treating a connector assembly that has been securely crimped.
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
C25D 5/50 - Post-traitement des surfaces revêtues de métaux par voie électrolytique par traitement thermique
32.
PRESSURE SENSOR, AND SENSOR UNIT PROVIDED WITH SAME
When the main body of a sensor chip (1) is in a grounded state, a shield layer (71) constituting a shield electrode formed on a circuit layer (72) is grounded through a resistor (46).
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
33.
DEVICE MEMBER COMPRISING CAVITY AND PRODUCTION METHOD FOR DEVICE MEMBER COMPRISING CAVITY
[Problem] To provide a device member and a production method therefor, said device member having an expected function as a device and being capable of forming, in a simple step, a cavity having a prescribed shape for an expected purpose, without the risk of a sealing layer penetrating inside the cavity and filling the cavity. [Solution] A device member comprising: a substrate member (12) comprising a semiconductor; an insulating intermediate layer (14) formed on the upper surface of the substrate member (12); an upper surface layer (16) comprising a semiconductor formed on the upper surface of the intermediate layer (14); an opening (18) formed on the upper surface layer (16); and a gas-permeable sealing layer (20) formed so as to seal the opening (18). The cavity (22) is formed by removing the intermediate layer (14) by using etching gas that has been passed through via the sealing layer (20).
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
B81B 3/00 - Dispositifs comportant des éléments flexibles ou déformables, p.ex. comportant des membranes ou des lamelles élastiques
B81C 1/00 - Fabrication ou traitement de dispositifs ou de systèmes dans ou sur un substrat
H01L 29/84 - Types de dispositifs semi-conducteurs commandés par la variation d'une force mécanique appliquée, p.ex. d'une pression
34.
ELECTROMAGNETIC CONTROL VALVE AND METHOD FOR ASSEMBLING ELECTROMAGNETIC CONTROL VALVE
An electromagnetic control valve (10) configured so that force acting on a valve body (21) is cancelled by a differential pressure using a diaphragm (3), wherein the pressure resistance and durability of the diaphragm (3) are improved. A needle-like protrusion (231) is formed at the lower end of the piston section (23) of a valve rod (2). An insertion hole (17c1) is formed at the center of a diaphragm guide (17c). The needle-like protrusion (231) is punctured through the center of the diaphragm (3). The needle-like protrusion (231) is inserted through the insertion hole (17c1) of the diaphragm guide (17c). An end of the needle-like protrusion (231) is spot-welded. Puncturing the diaphragm (3) with the needle-like protrusion (231) connects the diaphragm (3) to the valve rod (2) without cutting the base cloth (3A) of the diaphragm (3). Alternatively, a needle-like protrusion (17c2) is formed on the diaphragm guide (17c), an insertion hole (232) is formed in the valve rod (2), and the needle-like protrusion (17c2) is press fitted into the insertion hole (232).
The invention improves the pressure tightness and durability of the diaphragm (3) in an electromagnetic control valve (10) that is configured to cancel the force acting on the valve body (21) due to differential pressure using a diaphragm (3). A needle-shaped projection (231) is formed on the lower end of the piston section (23) of a valve rod (2), which is the drive shaft. An insertion hole (17c1) is formed in the center of a diaphragm guide (17c). The needle-shaped projection (231) is pierced through the center of the diaphragm (3). The needle-shaped projection (231) is inserted in the insertion hole (17c1) of the diaphragm guide (17c). The end of the needle-shaped projection (231) is spot-welded. The base fabric (3A) of the diaphragm (3) is fixed to the valve rod (2) without being cut by piercing the diaphragm (3) with the needle-shaped projection (231). It is also possible to form a needle-shaped projection (17c2) on the diaphragm guide (17c), form an insertion hole (232) in the valve rod (2), and press fit the needle-shaped projection (17c2) into the insertion hole (232).
[Problem] To provide an inexpensive and compact filter device disposed in a moist fluid flow path of a fuel cell system, wherein water neither adheres to nor remains in a filter, and the filter can be reliably prevented from being clogged due to freezing even when being left under low temperature after the system is stopped, and further, unlike conventional filter devices, complicated control and a heat source such as a defrosting heater are unnecessary. [Solution] A filter device (50) is disposed in a moist fluid flow path of a system in which a fluid has a water content, and is provided with: a fluid introduction path (58) through which the fluid passing through the moist fluid flow path is introduced into a filter chamber (60) from below the filter chamber (60); a filter (62) which is provided with a filter member (66) for transmitting the fluid introduced from the fluid introduction path (58) into the filter chamber (60) therethrough to remove foreign matter in the fluid, and is disposed in the filter chamber (60); a water storage part (72) which is provided below the filter (62); and a fluid discharge path (70) through which the fluid that has passed through the filter (62) is discharged.
The present invention allows a joint, bellows, and an actuation section to be easily combined with the main body of a pressure-activated switch, and the pressure-activated switch to be made small by eliminating the use of a cap or the like at the part where the joint is attached. The bellows (12) is connected with the joint (11) in order to construct a joint unit (1). A slit section (112a) is formed on the base of a hexagonal section (112) of the joint (11), said base part being positioned on a junction section's (111) side. A hexagonal insertion hole (21a) is created on the bottom plate (21) of a reinforcement plate (2), and the hexagonal section (112) is fitted into the insertion hole (21a). An actuation section (4) is combined with the reinforcement plate (2) in order to construct an assembly (10). Fixation claws (22a, 23a) are formed on the reinforcement plate (2). An insertion hole (31a) and a notch section (31b) are formed on the bottom plate (31) of a support case (3). Fixation holes (32a) are created on the back plate (32). The joint (11) is inserted through the insertion hole (31a), and a slit press-fitting section (31c) is press-fitted to the slit section (112a). The fixation claws (22a, 23a) are inserted through the fixation holes (32a) and bent. The corners of the hexagonal section (112) of the joint (11) are swaged toward the support case (3).
H01H 35/32 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un soufflet
[Problem] To operate the compressor reliably in the unloaded mode at the minimum capacity without using a magnetic clutch, etc. and to configure the variable capacity compressor to be small. [Solution] A pressure-sensing bellows (16) is disposed inside a bellows-housing chamber (13). A valve body (9) is opened and closed by abutting the valve body (9) against the pressure-sensing bellows (16). The impelling force of a plunger spring (36) is set to be stronger than the impelling force of a valve-opening spring (15). When the electromagnetic coil device (30) is de-energized, the impelling force of the plunger spring (36) causes the pressure-sensing bellows (16) to contact the valve body (9) via the plunger (35). If the suction pressure (Ps) inside the bellows-housing chamber (13) changes, the pressure-sensing bellows (16) is expanded or contracted while the valve body (9) side is kept stationary, allowing the plunger (35) to move freely and keeping the valve body (9) from moving, and unloaded operation is maintained. When the electromagnetic coil device is energized, the valve body side of the pressure-sensing bellows is kept stationary and unloaded operation is maintained.
F16K 17/06 - Soupapes ou clapets de sûreté; Soupapes ou clapets d'équilibrage fermant sur insuffisance de pression d'un côté actionnés par ressort avec dispositions particulières pour régler la pression d'ouverture
F04B 49/00 - Commande des "machines", pompes ou installations de pompage ou mesures de sécurité les concernant non prévues dans les groupes ou présentant un intérêt autre que celui visé par ces groupes
F16K 31/126 - Moyens de fonctionnement; Dispositifs de retour à la position de repos actionnés par un fluide le fluide agissant sur un diaphragme, un soufflet ou un organe similaire
Disclosed is a pressure-sensitive control valve which reliably minimizes the capacity of a variable capacity compressor in an unload operation without using a magnet clutch, etc., and reduces the size of the variable capacity compressor. A pressure-sensitive bellows (16) is disposed within a bellows storage chamber (13). A ball (11a) is abutted against the pressure-sensitive bellows (16), to open or close a valve body (9) via a stem portion (11). The biasing force of a plunger spring (36) is set to be larger than the biasing force of a valve closing spring (15). When an electromagnetic coil device (30) is not energized, the pressure-sensitive bellows (16) is abutted against a valve main body via a plunger (35) by the biasing force of the plunger spring (36). Depending on the variation of a suction pressure (Ps) within the bellows storage chamber (13), the pressure-sensitive bellows (16) is expanded or contracted with respect to the abutment portion with the valve main body, functioning as a fixed point, so that the plunger (35) is freely moved, but the valve body (9) is not moved, and thus, the unload operation is maintained. Alternatively, when the electromagnetic coil device is energized, the pressure-sensitive bellows (16) is expanded or contracted with respect to the abutment portion with the valve main body, functioning as a fixed point, to maintain the unload operation.
F16K 31/10 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un aimant avec mécanisme additionnel entre l'armature et l'élément de fermeture
F16K 31/06 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un aimant
F16K 31/126 - Moyens de fonctionnement; Dispositifs de retour à la position de repos actionnés par un fluide le fluide agissant sur un diaphragme, un soufflet ou un organe similaire
40.
PRESSURE-SENSITIVE DEVICE AND METHOD OF WELDING JOINT OF PRESSURE-SENSITIVE DEVICE
In a pressure-sensitive device that detects the pressure of fluid introduced into a cap member (2) via a joint (1), the joint (1) and the cap member (2) are securely connected. A washer-like nickel plate (3) is interposed between a flange portion (11) of the copper joint (1) and a stainless-steel cap member (21). Laser-welding is performed over the entire circumference of the outer peripheral edge (31) of the nickel plate (3). The nickel plate (3), a part of the flange portion (11), and a part of a flat portion (21) are melt and welded, and form a melt-solidified layer. The melt-solidified layer is formed over the entire circumference around an axis L between the flange portion (11) of the joint (1) and the flat portion (21) of the cap member (2). The melt-solidified layer is formed so as to enter deeply from the outer peripheral edge (31) of the flange portion (11) toward the axis L of the joint (1) between the flat portion (21) and the flange portion (11). The melt-solidified layer (A1) is composed of copper, nickel, and iron that are melt and solidified, and the joint (1) and the cap member (2) are securely welded.
B23K 20/00 - Soudage non électrique par percussion ou par une autre forme de pression, avec ou sans chauffage, p.ex. revêtement ou placage
F16L 13/02 - Raccords soudés à l'autogène sans apport de métal
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
Provided is a low-cost and compact filter device which is disposed in a moist fluid passage of a fuel battery system, wherein water is not attached to or does not remain in a filter, and the filter can be reliably prevented from clogging due to freezing even when the filter is maintained under a low temperature after the system is stopped and, additionally, a complicated control, and a heat source such as an unfreezing heater, etc., which have been necessary, are not necessary. The filter device which is disposed in a moist fluid passage of a fuel battery system is provided with a fluid introduction path which introduces fluid passing through the moist fluid passage, a filter through which the fluid introduced from the fluid introduction path passes, to remove foreign substances from the fluid, a fluid discharge path through which the fluid which has passed through the filter is discharged, and a rotary drive mechanism connected to the filter, which rotates the filter to remove substances attached to the filter, using a centrifugal force.
H01M 8/04 - Dispositions auxiliaires, p.ex. pour la commande de la pression ou pour la circulation des fluides
H01M 8/10 - PROCÉDÉS OU MOYENS POUR LA CONVERSION DIRECTE DE L'ÉNERGIE CHIMIQUE EN ÉNERGIE ÉLECTRIQUE, p.ex. BATTERIES Éléments à combustible; Leur fabrication Éléments à combustible avec électrolytes solides
A pressure sensing device for detecting, by means of a pressure detecting section (2), the pressure of a fluid introduced through a joint (1) into a cap member (21) ensures reliable joining of the joint (1) and the cap member (21), and simplification of the production process so as to reduce intermediate storage of goods in process. A washer-like clad member (3) is disposed between a base portion (11) of the joint (1), which is made of brass, and the cap member (21), which is made of stainless steel. The clad member (3) has a first layer (31) made of stainless steel and facing the cap member (21), and a second layer (32) made of oxygen-free copper and facing the base portion (11). The entire periphery of the joining portion of the first layer (31) and the cap member (21) is welded by laser, resulting in formation of a welding mark (7). The entire periphery of the joining portion of the second layer (32) and the base portion (11) is welded by laser, resulting in formation of a welding mark (8). A release mark (8a) is formed to attenuate the output of the laser light while releasing the laser light towards the base portion (11)-side.
G01L 19/04 - Moyens pour compenser les effets des variations de température
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
G01L 19/00 - MESURE DES FORCES, DES CONTRAINTES, DES COUPLES, DU TRAVAIL, DE LA PUISSANCE MÉCANIQUE, DU RENDEMENT MÉCANIQUE OU DE LA PRESSION DES FLUIDES - Détails ou accessoires des appareils pour la mesure de la pression permanente ou quasi permanente d'un milieu fluent dans la mesure où ces détails ou accessoires ne sont pas particuliers à des types particuliers de manomètres
A water discharge pump configured in such a manner that, with a cylindrical suction opening (12) immersed in a drain pan, a small impeller (22) within the suction opening (12) is rotated to suck water into the suction opening (12), wherein the quietness is obtained by preventing air from being sucked. The suction opening (12) is provided with a reduced-diameter section (12a) located in the middle of the inside of the suction opening (12) and formed by reducing the inner diameter of the suction opening (12). The reduced-diameter section (12a) is located at a position which is about 30%-50% of the overall length of the small impeller (22) from the lower end (221) of the small impeller (22). The amount of water is controlled by reducing the gap between the suction opening (12) and the small impeller (22) by the reduced-diameter section (12a), and this causes the water within the drain pan to be at a satisfactory level even in a balanced state and prevents air from being sucked. The adhesion of slime is also prevented by a reverse flow at the reduced-diameter section (12a).
A pressure sensitive device configured in such a manner that the pressure of fluid is detected by a pressure sensing section (2) by introducing the fluid through a female threaded coupling (1) into a pressure container which comprises a cap member (21), wherein the female threaded coupling (1) and the cap member (21) are reliably connected together without brazing and the production process is simplified to reduce the intermediate inventory of products being processed. A stainless steel intermediate coupling (3) is provided between the brass female threaded coupling (1) and the stainless steel cap member (21). A tilted surface (13) is formed between the threaded hole (11) and a cylindrical hole (12) of the female threaded coupling (1). A cylindrical section (31) of the intermediate coupling (3) is fitted in the cylindrical hole (12) of the female threaded coupling (1), and the periphery of the contact section between a flat section (31A) of the cylindrical section (31) and a flat section (21A) of the cap member (21) is welded by laser. A tilted flange section (32) of the intermediate coupling (3) is pressed against the tilted surface (13) by means of a male threaded coupling (5) (FIG. 3) on the piping side to cause the tilted surface (13) and the tilted flange section (32) of the intermediate coupling (3) to be in close contact with each other.
G01L 19/00 - MESURE DES FORCES, DES CONTRAINTES, DES COUPLES, DU TRAVAIL, DE LA PUISSANCE MÉCANIQUE, DU RENDEMENT MÉCANIQUE OU DE LA PRESSION DES FLUIDES - Détails ou accessoires des appareils pour la mesure de la pression permanente ou quasi permanente d'un milieu fluent dans la mesure où ces détails ou accessoires ne sont pas particuliers à des types particuliers de manomètres
G01L 9/00 - Mesure de la pression permanente, ou quasi permanente d’un fluide ou d’un matériau solide fluent par des éléments électriques ou magnétiques sensibles à la pression; Transmission ou indication par des moyens électriques ou magnétiques du déplacement des éléments mécaniques sensibles à la pression, utilisés pour mesurer la pression permanente ou quasi permanente d’un fluide ou d’un matériau solide fluent
H01H 35/34 - Interrupteurs actionnés par le changement de pression du fluide, par les ondes de pression du fluide, ou par le changement d'écoulement du fluide actionnés par un diaphragme
A pressure-operated control valve having a configuration in which a valve element is pressed against a valve seat by the spring force of a diaphragm and the valve is opened when the diaphragm starts to deform due to a set pressure of fluid, wherein the liquid is prevented from leaking in the initial stage of deformation of the diaphragm. A ball valve (2) and a valve rod (3) are arranged within a valve chamber (13). A valve port (14) is opened and closed by the ball valve (2). A coiled spring (5) is disposed within a spring chamber (16), and the valve rod (3) is pressed against a diaphragm (7) through a spring receiver (31) of the valve rod (3). The diaphragm (7) comprises a cone section (71) and a flat section (72) (or a recessed section) located inside the cone section. The diameter of a diaphragm-side end surface (3A) of the valve rod (3) is set to be greater than the diameter of the flat section (72) of the diaphragm (7). The configuration causes a boundary portion (74) which is the boundary between the cone section (71) and the flat section (72) to make contact with the diaphragm-side end surface (3A) in the initial stage of deformation of the diaphragm (7).
A flow path selector valve for switching between a cooling state and a heating state by rotation of a main valve (3) together with a auxiliary valve (4), wherein rotational operation of the main valve (3) and the auxiliary valve (4) are simplified to make operation of the main valve (3) reliable and to reduce a switching time. An outdoor heat exchanger-side communication passage (31A) and an indoor heat exchanger-side communication passage (31B) are formed in the main valve (3). An outdoor heat exchanger-side equalizing hole (34a) for connecting the outdoor heat exchanger-side communication passage (31A) to a valve chamber (11) is formed in the main valve. An indoor heat exchanger-side equalizing hole (34b) for connecting the indoor heat exchanger-side communication passage (31B) to the valve chamber (11) is formed in the main valve (3). A closing section (43A) for closing the outdoor heat exchanger-side equalizing hole (34a) and an equalizing hole opening section (45B) for opening the indoor heat exchanger-side communication passage (34b) are also formed in the auxiliary valve (4). A closing section for closing the indoor heat exchanger-side equalizing hole (34b) and an equalizing hole opening section for opening the outdoor heat exchanger-side communication passage (34a) are also formed in the auxiliary valve. A support section sliding on a auxiliary valve seat (34) is formed on the auxiliary valve (4). The main valve (3) is rotated 90° by merely operating the auxiliary valve (4) in either forward or reverse directions, and this switches between the cooling state and the heating state.
F16K 11/076 - Soupapes ou clapets à voies multiples, p.ex. clapets mélangeurs; Raccords de tuyauteries comportant de tels clapets ou soupapes; Aménagement d'obturateurs et de voies d'écoulement spécialement conçu pour mélanger les fluides dont toutes les faces d'obturation se déplacent comme un tout comportant uniquement des tiroirs à éléments de fermeture articulés à pivot à faces d'obturation épousant la surface d'un solide de révolution
F16K 31/04 - Moyens de fonctionnement; Dispositifs de retour à la position de repos magnétiques utilisant un moteur
F16K 31/53 - Moyens mécaniques d'actionnement à engrenage
F25B 13/00 - Machines, installations ou systèmes à compression, à cycle réversible
[PROBLEMS] To provide a quiet and durable pressure type expansion valve for an air conditioner by reducing vibration of a valve body (2) caused by the flow of a refrigerant. [MEANS FOR SOLVING PROBLEMS] In a valve housing (1), an inlet port (11), a valve chamber (1A), and an outlet port (12) are generated. Between the valve chamber (1A) and the outlet port (12), a valve seat part (3) is disposed. On the valve seat part (3), a valve port (31) and an orifice (32) are formed. Surrounding the valve body (2), a coil spring (4) is disposed to hold the valve body (2). A valve opening area of the valve body (2) and the valve port (31) is controlled depending on the differential pressure between a refrigerant pressure in a pressure control chamber (1B) communicated with the valve chamber (1A) and the atmospheric pressure in the inner space (51A) of bellows (51). The orifice (32) is formed inside the outer diameter of the valve body (2), on the opposite side of the inlet port (11). The suction force of the refrigerant flowing through the orifice (32) is made to act on the valve body (2) in one direction. The orifice (32) is positioned inside the coil spring (4). Cutting off the refrigerant by the coil spring (4) equalizes force acting on the valve body (2).
A flow rate control valve has a first opening (27) facing a valve chamber (25) of a valve housing (26); a second opening (29) where a valve seat (28) facing the valve chamber (25) of the valve housing (26) is formed; a valve body (30) movably held so as to close the second opening (29); and a drive means (31) for driving the valve body (30). Further, the valve body (30) has at least one restriction path (46); a first gap section (47) at whose center one end of the restriction path (46) is opened; a first port (51) for communicating an outer peripheral section of the first gap (47) and the valve chamber (25) of the valve housing (26); a second gap (48) at whose center the other end of the restriction path (46) is opened; and a second port (52) communicating with an outer peripheral section of the second gap (48) and facing the second opening (29).
An electrically operated control valve, in which a valve body side spring retainer member is in contact with a stopper surface section, provided on a valve holder, to limit the movement of the valve body side spring retainer member to the lower lip section side; the valve body side spring retainer member is in contact with the stopper surface section to be separated from a valve body until a male screw shaft moves, by a distance equal to or more than a predetermined value, from a position where the valve body is seated on a valve seat section further to the valve seat section side; and, as a result, the valve body side spring retainer member and the valve body are separated, causing spring force of a compression coil not to act on the valve body. By this, wear at the surface where the valve body and the valve seat section are in contact is reduced, and leakage in a totally closed state is less likely to occur for a long period.
In a conventional water discharge pump assembled in an air conditioner, the rotation of a blade wheel produces cavitation to cause a problem with quietness. A vertical shaft water discharge pump of the invention has a rotor (23), a casing (20), a cover (22) that forms, together with the casing (20), a pump chamber (21) in which the rotor (23) is received, a suction pipe (25) forming a suction path (24) communicating with a lower end central portion of the pump chamber (21), and a discharge port (26) communicating with the pump chamber (21). The rotor (23) has a rotor shaft (40) connected at its upper end section to a drive motor (16), a circular main plate (42) cocentrically integrally connected to the rotor shaft (40), pins (43) projecting from the main plate (42) substantially in parallel to the axis of the rotor shaft (40), and uniformly pressing sections (44, 46) formed in the main plate (42) and communicating between the front surface side and the back surface side of the main plate (42).