JP4125680B2 - Hydraulic damper - Google Patents

Abstract

Disclosed is a hydro damper for absorbing pressure oscillations and/or acoustic vibrations in systems which are operated by means of pressurized fluids. The inventive hydro damper is provided with a housing ( 1 ) having a leading dimension which defines a longitudinal axis ( 3 ) of the housing, a connection block ( 5 ) fluidically connecting the damper housing ( 1 ) to the corresponding system, and a linking device ( 7, 47, 49 ) which is assigned to the connection block ( 5 ) so as to mount the connection block ( 5 ), and consequently the damper housing ( 1 ), on the system in selected rotational positions relative to an axis of connection ( 41 ) that runs perpendicular to the longitudinal axis ( 3 ) of the housing.

Description

  The present invention relates to a hydraulic damper for attenuating pressure and / or acoustic vibrations in a device operated by a pressurized fluid.

  In hydraulic systems, devices that excite various types of processes produce pressure fluctuations that can be caused by, for example, rapid connection of spaces of different pressure levels, short shut-off times or activation of control fittings. And the discontinuous operation caused by the pump pulsation in the positive displacement pump, and further the on / off switching process of the positive displacement pump.

  Differently designed damper devices are used to dampen pressure fluctuations, periodic pressure fluctuations or acoustic vibrations. Accordingly, the hydraulic damper can be made based on the principle of hydropneumatic bladder type and diaphragm accumulator, or can be made as a reflection damper (silencer).

  A general requirement for the effect of a hydraulic damper is that the damper housing is relatively large in volume; this increases the size of the damper housing. When installing a hydraulic device, the installation space available in the machine room is limited, and a hydraulic pump is installed in the machine room, and pressure vibration and acoustic vibration due to pump pulsation are generated at the pump output. If a damping hydraulic damper has to be connected, a problem often arises due to the space requirement of the hydraulic damper with a relatively large volume damper housing. This problem results in an increase in the hydraulic system in the injection molding machine, which requires good damper operation at the output of the associated hydraulic pump, but generally the installation space available for large volume damper housings is very high It has become limited.

  An object of the present invention is to provide a hydraulic damper having a structure that is a relatively large-capacity damper housing and can be attached to a related hydraulic apparatus even when the installation space is limited.

This object is achieved by a hydraulic damper as defined in claim 1, wherein the hydraulic damper comprises a damper housing, a connection block and a link means:
The damper housing has a major dimension defining a longitudinal axis of the damper housing;
The connection block is for fluidly connecting the damper housing with an associated device;
The link means is for a connection block for attaching the connection block and thus the damper housing to the device in a selectable rotational position relative to the connection shaft, the connection shaft being connected to the damper housing. Crosses the longitudinal axis.

That is, as defined in the present invention, the damper housing can be connected to an associated hydraulic device in a desired rotational position, and the damper housing extends in a direction in which the main dimensions of the damper housing optimally use the space. It can be accommodated in the related installation space in such a direction. As a result, the damper housing having an elongated structure and a relatively large volume can be accommodated in a narrow machine space.
The fact that the rotational position of the damper housing provided by the present invention can be selected around a connecting axis that intersects the longitudinal axis, for example, allows a direct connection to the associated hydraulic pump output. Even in a small installation space, for example, a reflection-type hydraulic damper that requires a relatively large-capacity damper housing can be directly connected to the associated hydraulic pump in a limited available space.

  Preferably, the connecting shaft is substantially perpendicular to the connecting shaft relative to the major dimension of the damper housing defining the longitudinal axis of the housing.

  In an advantageous embodiment, the linking means comprises a pump connection piece, the pump connection piece forming a fluid coupling between the connection block and the hydraulic pump and with respect to the connection shaft It can be fixed to the output of the hydraulic pump at selectable rotational positions.

  If the pump output is equipped with a joint of link parts based on the SAE standard, i.e. having a matching hole pattern for mounting screws, it is attached to the output of the hydraulic pump An annular body is provided as a pump connection piece of the linking means, the annular body comprising a ring of holes arranged along its outer periphery, the holes being connected to the connection shaft with respect to the connection shaft Corresponding to the desired rotational position and can be selected for engagement of mounting screws, the mounting screws are provided in the connection block. In this embodiment, the connection of the hydraulic damper to the pump output is possible at a rotation interval corresponding to the hole interval of the ring of holes in the pump connection piece.

  On the other hand, the pump connection piece has a circular flange, and the circular flange can be fixed at a selected rotational position with respect to the connection shaft by a clamping jaw of a semicircular SAE flange, and the clamp The jaws are screwed into the SAE connection at the output of the hydraulic pump to allow continuous rotational position selection.

  Detailed description will be given using the embodiment shown in the accompanying drawings.

  1 and 2 illustrate a first embodiment of the invention, in particular a reflection damper (silencer), which has an elongated damper housing 1 of major dimensions defining a longitudinal axis 3 of the housing. The damper housing 1 is fluidly connected to a connection block 5 at one end located on the right side in the figure, and the connection block 5 is connected to the output of a hydraulic pump (not shown) by a pump connection piece 7. Has been.

  The accumulator housing 1 extends coaxially with the longitudinal axis 3 between the inlet end portion 11 and the outlet end portion 13 of the damper housing 1 in a volume as a reflection type hydraulic damper, that is, as a resonator using an interference action. A damping pipe 9 is included. The damping pipe 9 has a slot opening 15 in the center thereof, and the slot opening 15 is used to transmit the fluid vibration in the damping pipe 9 to the fluid volume 7 surrounding the damper pipe 9 inside the damper housing 1. Is. Since the holes 19 provide for permanent ventilation of the space containing the volume 17, the hydraulic damper does not need to be pre-filled at the start. This is because accumulated air is discharged from the hole 9.

  Each of the inlet end portion 11 and the outlet end portion 13 of the damper housing has a female screw 21 into which a screw piece 23 is screwed; both ends of the damping pipe 9 are concentric with the longitudinal shaft 3. 23 is held in the inner hole. The O-ring 25 seated in the inner hole of the screw piece 23 elastically supports the damping pipe 9, so that no small crossing is required, and the damping pipe 9 does not generate any noise during operation.

  Each of the inlet end portion 11 and the outlet end portion 13 in the damper housing 1 has a male screw 27. For example, a connection flange 29 is screwed into a male thread 27 at the outlet end 13 in order to connect to the device to be used by means of a SAE joint means such as a pressure hose. The connection block 5 is screwed into the male screw 27 at the inlet end 11 in the damper housing 1, and the screw seal 31 is provided on the male screw 27. A connection block 5 having an internal chamber 33 fluidly connected to the damper housing 1 forms a main chamber for the resonator device installed in the damper housing 1. In the bottom opening 35, the chamber 33 of the connection block 5 is connected to the output of a hydraulic pump (not shown) via the pump joint 7.

  As is apparent from FIG. 2, the connection block 5 has four holes 37 for engaging mounting screws (not shown), and the connection block 5 is attached to the pump connection piece 7 using the mounting screws. Yes. The pump connection piece 7 is an annular body in the embodiment illustrated in FIGS. 1 and 2 and can be connected to the output of the hydraulic pump for the purpose of interacting with the hole 37 in the connection block 5. The ring of the hole 39 is arranged concentrically with the connecting shaft 41 and with the same radius as the hole 37 of the connecting block 5, and the connecting shaft 41 is a longitudinal axis of the housing. 3 and defines the center of the opening 35 connecting the chamber 33 to the hydraulic pump. Therefore, the connection block 5 can be rotated around the connection shaft 41 in order to produce an alignment between the desired hole 39 of the ring of holes in the pump connection piece and the hole 37 in the connection block 5. The damper housing 1 can have its longitudinal axis 3 aligned with a desired rotational position with respect to the connecting shaft 41. When attaching the damper housing 1 to the associated hydraulic pump, the longitudinal direction of the damper housing 1 can be rotated to a position where space utilization is optimized under the respective installation conditions. That is, this means that the damper housing 1 having a relatively large volume can be installed even under different installation conditions.

  In the embodiment in FIGS. 1 and 2, the rotational position of the damper housing 1 can be set at intervals corresponding to the space of the hole 39 in the outer periphery of the pump connection piece 7, which is made as an annular body. On the other hand, in the embodiment in FIG. 3, the rotational position of the damper housing 1 around the connection shaft 41 can be set continuously. For this purpose, in a second embodiment, the pump connection piece 7 is not made as an annular body with a perimeter ring of holes, but in the form of a cylindrical hollow body used as a fluid supply pipe, The fluid supply pipe forms an internal chamber 3 in the connection block 5 together with the output of the hydraulic pump, the output of which is illustrated at 43 and schematically illustrated in FIG. The hollow body of the pump connection piece 7 is concentric with the connection shaft 41 for fluid contact with the internal chamber 33 of the connection block 5 and has a wall surface through hole 45, and the through hole 45 is formed in the damper housing 1. It is the same height as the longitudinal axis 3.

  The pump connection piece 7 has a flange 47 at the open end which projects from the connection block 5 and can be attached to a pump output 43 for fluid inlet. The pump connection piece 7 is fixed to the pump output 43 by a half ring-shaped flange clamp jaw 49 which is common to the connecting link according to the SAB standard (J518). By rotating the circular end of the flange 47 in the pump connection piece 7 in the clamp jaw 49 that annularly surrounds the end of the flange 47, the rotational position around the connection shaft 41 is continuously selected as desired. can do.

  Needless to say, damper devices having different operation modes may be attached to the connection block 5 instead of the damper housing 1 of the reflection damper shown as two embodiments. The damper device having different operation modes is, for example, a hydraulic damper based on the principle of a hydropneumatic bladder type and a diaphragm accumulator.

  The hydraulic damper in the claims of the present invention may be used in a specific type of original equipment of a plastic injection molding machine. Based on the space requirements in each machine, suitable holes in the pump connection piece are provided on top of the current hole pattern, which can be used to omit complex hole patterns in the pump connection piece. it can. In fact, it is possible to select a hole pattern, in which the hydraulic damper can be mounted in a desired position according to the type of plastic injection molding machine.

FIG. 1 is a schematic side view of a first embodiment of a hydraulic damper. FIG. 2 is a longitudinal sectional view of the embodiment in FIG. 1 and is shown on a larger scale as compared to FIG. FIG. 3 is a perspective view of a rear portion of the second embodiment of the hydraulic damper, in which the hydraulic damper is connected to the hydraulic pump by an SAE joint, and a part of the hydraulic damper is illustrated in a large scale.

Claims (6)

A hydraulic damper for attenuating at least one of pressure oscillation及beauty acoustic vibrations in the device which is actuated by a pressurized fluid; damper housing (1) and connection block (5) and a link means (7) In the hydraulic damper equipped:
The damper housing (1) has a main dimension defining a longitudinal axis of the damper housing;
The connection block (5) is for fluidly connecting the damper housing (1) with an associated device;
The link means (7) is for a connection block (5), and the connection block (5) and thus the damper housing (1) is connected to the device in a rotational position selectable with respect to the connection shaft (41). is intended for mounting, the connection shaft (41) intersects the said long Tejiku (3) of the damper housing;
The link means has a pump connection piece (7), the pump connection piece (7) forming a fluid coupling between the connection block (5) and the hydraulic pump and the connection shaft In a rotational position selectable with respect to (41), so that it can be fixed to the output (43) of the hydraulic pump;
The pump connection piece (7) is adapted to be attached to the output (43) of the hydraulic pump, the output having a connection for forming a SAE standard flange joint, The pump connection piece (7) has a circular flange (47), which was selected with respect to the connection shaft (41) by means of a clamping jaw (49) of a semi-circular SAE flange Can be fixed in a rotational position, the clamp jaw (49) being screwed into the SAE connection at the output (43) of the hydraulic pump;
Hydraulic damper. The hydraulic damper according to claim 1, wherein the connecting shaft (41) is at least approximately perpendicular to the longitudinal axis (3) of the damper housing. The pump connection piece (7) has an annular body that can be attached to the output (43) of the hydraulic pump, the annular body being a ring of holes (39) arranged along its outer periphery The hole (39) corresponds to a desired rotational position of the connecting block (5) relative to the connecting shaft (41) and can be selected for engagement of mounting screws, 2. The hydraulic damper according to claim 1, wherein a screw is provided on the connection block (5). The connecting block (5) has an internal chamber (33) with an outlet opening, the internal chamber (33) extending concentrically with the longitudinal axis of the damper housing and the damper housing ( 1) connected to the input (11); like the pump connection piece (7), there is a cylindrical hollow body, which is concentric with the connecting shaft (41) and Extending perpendicularly to the longitudinal axis of the damper housing into the internal chamber (33) of the connection block (5), the cylindrical hollow body being used as a fluid supply pipe, A wall through-hole (45), the wall through-hole (45) being connected to the longitudinal axis of the damper housing for fluid connection with the internal chamber (33) of the connection block (5). Concentric with (3) Hydraulic damper according to any one of claims 1 to 3. The hydraulic damper according to claim 4, wherein the damper housing (1) contains a reflection type fluid silencer (9) and the damped pressurized fluid flows through the fluid silencer (9). The internal chamber (33) of the connection block (5) is connected to an input (11) of the fluid silencer (9) and is provided as a prechamber of the fluid silencer (9). 5. The hydraulic damper according to 5.

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