RU185432U1 - SWITCHING VALVE - Google Patents

Abstract

A switching valve is proposed in which compressed air is used not only to determine the position of the valve element, but also selectively, depending on the situation, as a driving force for the fluid compressor. The switching valve comprises a first valve section 10 that switches the first flow passage containing a plurality of main channels, and a second valve section 30, which switches a second flow passage containing a plurality of auxiliary channels and isolated from the first flow passage, in which I valve section comprises a main chamber 12 communicating with the main channels, the main valve member 13 disposed in the main chamber and configured to switch a connection state between the main channels, and a valve driving section which drives the main valve member; the second valve section comprises an auxiliary chamber 32 in communication with the auxiliary channels, and an auxiliary valve element 33 located in the auxiliary chamber and configured to switch connection states between the auxiliary channels; wherein the main chamber and the auxiliary chamber, and the main valve element and the auxiliary valve element, respectively, are located on the same axis L; and the main valve element and the auxiliary valve element perform the switching operation synchronously.

Description

Technical field

[0001] The present utility model relates to a switching valve that switches connection states between a plurality of channels that communicate with the camera by moving a valve member located in the camera.

State of the art

[0002] A switching valve is known which switches connection states between a plurality of channels that communicate with the camera by moving a valve member located in the camera. For example, Japanese Patent Application Publication No. 2014-228081 (Patent Source 1) describes a switching valve comprising a chamber formed in a valve body, a valve member located in the chamber, and a plurality of inlet and outlet channels that communicate with a camera. The switching valve is configured to supply control air driving the piston to the pistons located at both ends of the valve element so as to move the valve element in the axial direction of the chamber. As the valve element moves, the connection states between the plurality of channels are switched to supply and output compressed air to and from the gas compressor connected to the exhaust channel.

[0003] This type of switching valve comprises a switching valve having a direction determining mechanism for determining a switching position of the valve element, as described in Japanese Examined Patent Application No. 2003-74742 (Patent Source 2). The switching valve described in Patent Source 2 comprises a piston connected to the valve element, a magnet embedded in the piston, a magnetic sensor located around the piston chamber, and a switching circuit integrated in the switching valve for converting the resistance of the magnetic sensor into an electrical signal, and with the ability to detect a magnet that moves with the valve element based on an electrical signal converted by a switching circuit.

However, determining the position of the valve element using electricity, as in the switching valve of Patent Source 2, is not preferred in an environment in which electricity or static electricity is undesirable. Accordingly, in determining the position of the valve element in such an environment, air is preferably used. In this case, for example, air is directed to a display device, such as a pneumatic indicator, and the position of the valve element is determined based on the state of such a display device. Additionally, it is further preferred that air can be used not only to determine the position of the valve element, but also as a drive force for an actuator and the like, selectively depending on the situation.

List of sources

Patent Literature

[0004]

The closest analogue is Patent Source 1: Japanese Unexamined Patent Application No. 2014-228081.

Name: Pilot Type Solenoid Valve

Application Date: May 23, 2013

Application Number: JP2013-109071

Publication Date: December 8, 2014

Patent Source 2: Japanese Unexamined Patent Application No. 2003-74742.

Brief Description of Utility Model

Technical challenge

[0005] Accordingly, the objective of the present utility model is to provide a switching valve in which compressed air is used not only to determine the position of the valve element, but also as a driving force for a gas compressor selectively depending on the situation.

The solution of the problem

[0006] To solve the above problem, a switching valve according to one aspect of the present utility model comprises: a first valve section that switches a first flow passage formed by a plurality of main channels; and a second valve section that switches the second flow passage formed by a plurality of auxiliary channels isolated from the first flow passage, in which the first valve section and the second valve section are located at one end and the other end of the valve body, respectively; wherein the first valve section comprises a main chamber, which communicates with the main channels; a main valve element located in the main chamber and configured to switch connection states between the main channels; and a valve drive section, wherein the second valve section comprises an auxiliary chamber that communicates with the auxiliary channels, and an auxiliary valve element located in the auxiliary chamber and configured to switch connection states between the auxiliary channels, wherein the main camera, auxiliary camera, main valve the element and the auxiliary valve element are respectively coaxial on the axis, and the main valve element and the auxiliary valve element are olnyayut switching operations synchronously.

[0007] In the switching valve according to the above aspect of the present utility model, it is preferable that the first valve section is a two-position valve, in which the main valve element has a first switching position and a second switching position, and the second valve section is a two-position valve, in which the auxiliary valve element has the first switching position and the second switching position, and was a two-way distributor having two channels - an auxiliary inlet channel and an auxiliary exhaustive exhaust channel.

[0008] Here, the main valve member and the auxiliary valve member can be actuated by the valve driving section when moving from the first switching position to the second switching position, and can be driven by the return spring when moving from the second switching position to the first switching position.

[0009] Further, a valve stem may extend between the main valve member and the auxiliary valve member so that the main valve member and the auxiliary valve member are connected by the valve stem.

Hereinafter, it is preferable that the valve stem has an exhaust channel formed therein in communication with an auxiliary exhaust channel open to the atmosphere.

Positive effects of utility model

[0010] As described above, the switching valve according to one aspect of the present utility model comprises a first valve section that switches a first flow passage formed by a plurality of main channels, and a second valve section that switches a secondary flow passage formed by a plurality of auxiliary channels isolated from the first flow passage, and valve elements of the first and second valve sections are synchronized to switch flow passages. Accordingly, the air discharged from the auxiliary channel in the second valve section can be used to determine the switching position of the main valve element in the first valve section. Further, air can be used not only to determine the position of the main valve element, but also as a driving force for other actuators, in addition to the main section of the valve. The air discharged from the second section of the valve can be selectively used depending on the situation.

Brief Description of the Drawings

[0011]

FIG. 1 is a perspective view of the appearance of a switch valve embodiment according to the present utility model.

FIG. 2 is a side view in cross section of a switching state in which the valve driving section is in an off state.

FIG. 3 is a schematic view of a fragment A highlighted by a dash-dot line in FIG. 2.

FIG. 4 is a side view in cross section of a switching state in which the valve driving section is in an on state.

FIG. 5 is a schematic view of a fragment B highlighted by a dot-dash line in FIG. four.

FIG. 6 is a schematic exploded perspective view of the valve of FIG. one.

[0012] FIG. Figures 1-6 show an embodiment of a diverter valve according to the present invention. As shown in FIG. 1, the switching valve 1 of the present utility model comprises a first valve section 10 that switches the first flow passage for compressed air, and a second valve section 30 that switches the second flow passage for compressed air that is isolated from the first flow passage. The first valve section 10 and the second valve section 30 are located at one end and the other end of the valve body 2 in the direction of the L axis, respectively.

[0013] As shown in FIG. 2 or 4, the first valve section 10 comprises a main valve section 3 and a valve driving section 20. As shown in FIG. 1, 2 or 6, the main section 3 of the valve comprises a housing 11 having a rectangular section, a main chamber 12 formed as a circular hole in the housing 11 extending along the L axis, and a main valve element 13 in the form of a spool having a valve section 14 in the central position in the direction of the axis L. The valve section 14 of the main valve element 13 is made of an annular sealing material, for example synthetic rubber, and has a diameter larger than the shaft diameter of both ends 13a and 13b of the main valve element 14. Further, an annular sealing element 15 is installed at each end 13a, 13 of the main valve member 13. In addition, at 6 in FIG. 1 shows a mounting hole into which a fastening element, for example, a bolt, is inserted to fasten a switching valve to a fluid supply element, for example, on a manifold base.

[0014] As shown in FIG. 2 and 4, the main chamber 12 communicates with one main inlet channel P1, one main outlet channel A1, and one main outlet channel R1, which are open on the outer surface of the housing 11. Of these main channels, the main outlet channel A1 is located essentially in the center of the housing 11 in the direction of the axis L. The main inlet channel P1 and the main outlet channel R1 are located at both ends in the direction of the axis L so that the main outlet channel A1 is located between them. These three channels form the first flow passage in the switching valve 1 according to the present utility model.

[0015] Furthermore, as shown in FIG. 2 or 4, two tubular shaped sleeves 16 and 17 are arranged adjacent to each other in the main chamber 12 in the main chamber 12 so as to hold the main valve element 13 in a sliding manner.

Of these sleeves 16, 17, the first sleeve 16 is located on one open end of the main chamber 12 (next to the main outlet channel R1), and the second sleeve 17 is located next to the other open end of the main chamber 12 (next to the main inlet channel P1). A sealing element 18, such as a sealing ring, is arranged on the outer peripheral surface of the bushings 16, 17 so as to maintain the air tightness of the main chamber 12. In this embodiment, both ends 13a and 13b of the main valve element 13 are in sliding contact with the inner peripheral surface of the bushings 16 and 17.

[0016] Further, the bushings 16 and 17 have through holes 16a and 17a, respectively, which are in communication with the respective internal spaces of these bushings. The inner space of the first sleeve 16 communicates with the main outlet channel R1 and the main outlet channel A1 through the through hole 16a of the sleeve 16, and the inner space of the second sleeve 17 communicates with the main inlet channel P1 and the main outlet channel A1 through the through hole 17a of the sleeve 17. 16 and 17, which are opposite each other in the direction of the L axis, the annular first and second main valve seats 16b and 17b are located, respectively, so that the section 14 of the main valve element 13 comes into contact and exits of contact with the first and second main seats 16b and 17b of the valve.

[0017] As shown in FIG. 2 or 4, the valve drive section 20 comprises a cylindrical body 22 in which a blind hole 21 is formed, open into the main chamber 12, a drive piston 23 that slides in the hole 21 so as to divide the hole 21 into a first cylindrical chamber 21a which is adjacent to a main valve chamber 12, and a second cylindrical chamber 21b located opposite the first chamber 21a, and control channels 24 and 25, which communicate with the second chamber 21b and supply control fluid for driving the piston. In this embodiment, as shown in FIG. 1 or 6, the housing 11 and the body 22 are integrally fastened by a bolt 7 to thereby form a first valve section 10.

[0018] As shown in FIG. 2 or 4, the actuating piston 23 is connected to the other end 13b of the main valve element 13 so that the main valve element moves in the main chamber 12 when the actuating piston 23 moves in the hole 21. Further, a lip seal 27 is installed on the outer peripheral surface of the actuating piston 23. creating directional compaction. The flange of the lip seal 27 is oriented so as to allow the flow of control air from the first chamber 21a to the second chamber 21b, but to block the air flow from the second chamber 21b to the first chamber 21a.

[0019] Further, from the above control channels 24 and 25, one channel 24 allows the external control fluid to be supplied to the second chamber 21b, and the other channel 25 allows the air discharged from the supply channel P1 to enter the second chamber 21b through a control valve not shown in drawing. When the control air is supplied to the second chamber 21b through the control channels 24 and 25, this control air acts on the rear side (pressure receiving surface) of the drive piston 23 to move the drive piston 23 from the second cylindrical chamber 21b to the first cylindrical chamber 21a. Accordingly, the main valve member 13 is moved from a first switching position located adjacent to the other end 13b of the main valve member 13 (the position shown in FIG. 2) to a second switching position located adjacent to one end 13a of the main valve member (position shown in Fig. 4).

As shown in FIG. 2 and 4, of the two control channels 24 and 25 of the present embodiment, the second channel 25 is closed by a plug 26.

[0020] Furthermore, as shown in FIG. 2 and 4, next to the first end 13a of the main valve member 13, a main return spring 19 is located so as to constantly press the main valve member 13 toward the second end 13b. The main return spring 19 is designed as a cylindrical spring and is designed to return the main valve element 13 from the second switching position to the first switching position due to the force of compression of the spring.

As described above, the first valve section 10 has a two-position valve configuration that switches connection states between the respective main channels when the main valve element 13 is shifted between the first switching position and the second switching position.

[0021] As shown in FIG. 2 and 4, the first flow passage in the first valve section 10 is configured to create a connection state described below by switching the position of the main valve element 13.

That is, when the main valve member 13 is in the first switching position shown in FIG. 2, the section 14 of the main valve member 13 abuts against the second main seat 17b of the second sleeve 17, thereby opening a communication between the main outlet channel A1 and the main outlet channel R1 and blocking the flow passage between the main inlet channel P1 and the main outlet channel A1. Conversely, when the main valve member 13 is in the second switching position shown in FIG. 4, section 14 of the main valve member 13 abuts against the first main valve seat 16 b on the first sleeve 16, thereby opening a communication between the main inlet channel P1 and the main outlet channel A1 and blocking the flow passage between the main outlet channel A1 and the main outlet channel R1.

[0022] The following is a description of a second valve section 30.

As shown in FIG. 1, 2 and 4, and 6, the second valve section 30 comprises a housing 31 having a substantially cylindrical shape having a bottom auxiliary chamber 32 that is open to the first valve section 10 of the housing 31 (right side in FIG. 2), and an auxiliary valve an element 33 located in the auxiliary chamber 32. In this embodiment, the main chamber 12 of the first valve section 10 and the auxiliary chamber 32 of the second valve section 30 are aligned (that is, aligned on the axis L), and the main valve element 13 located in the main chamber 12 and auxiliary valve element nt 32 located in the auxiliary chamber 32 are aligned on the axis L. The following is a description of the specific configuration of the second valve section 30.

[0023] The second valve section 30 is formed by a two-way distributor having an auxiliary inlet channel P2 and an auxiliary outlet channel A2, which are in communication with the auxiliary chamber 32. The connection states between the respective auxiliary channels are switched by the auxiliary valve element 33 coming into contact and coming out of contact with an auxiliary valve seat 34 located in the auxiliary chamber 32. As described above, a second flow passage including an auxiliary inlet channel P2 and an auxiliary The exhaust outlet A2 is isolated from the first flow passage located in the first section 10 of the valve.

[0024] As shown in FIG. 3 or 5, in the auxiliary chamber 32, the first and second plates 35 and 36 are arranged in a tubular shape and are located at a predetermined distance from each other on the axis L. Of these plates 35 and 36, the first plate 35 is located in the flow passage between the auxiliary inlet channel P2 and auxiliary exhaust channel A2 in the auxiliary chamber 32, and on the outer peripheral surface of the first plate 35, an annular sealing element 37 is installed. On the other hand, the second plate 36 is located next to the opening of the auxiliary chamber 32 (adjacent to the first valve section 10) and a sealing element 37 is also mounted on the outer peripheral surface of the second plate 36.

[0025] Of these plates 35 and 36, the first plate 35 has a protrusion 35a that projects radially inward from the distal end (left side in FIGS. 3 and 5). Further, the protrusion 35a has an annular secondary valve seat 34, which protrudes in the direction of the bottom 32a of the auxiliary chamber 32.

[0026] As shown in FIG. 3 or 5, the auxiliary valve element 33 is a poppet valve element and is arranged to move in the direction of the L axis between the auxiliary valve seat 34 and the bottom 32a of the auxiliary chamber 32. The auxiliary return spring 38 is installed between the auxiliary valve element 33 and the bottom 32a for constantly pressing the auxiliary the valve element 33 to the auxiliary seat 34 of the valve. The auxiliary valve element 33 is biased between the first switching position in which the auxiliary valve element 33 is seated on the auxiliary valve seat 34 due to the compressive force of the spring 38 (see FIG. 3) and the second switching position in which the auxiliary valve element 33 is ejected by the valve stem 40 described above to get out of contact with the auxiliary seat 34 of the valve (see FIG. 5).

When the auxiliary valve member 33 is located in the first switching position, the auxiliary inlet channel P2 is isolated from the auxiliary outlet channel A2. When the auxiliary valve member 33 is located in the second switching position, the auxiliary inlet channel P2 is in communication with the auxiliary outlet channel A2. Thus, the second valve section 30 is constituted by a two-position valve, as is the first valve section 10.

[0027] Further, in the auxiliary chamber 32, a valve stem 40 is provided having a rod shape and extending in the direction of the axis L. The valve stem 40 is for connecting the main valve element 13 to the auxiliary valve element 33. When the main valve element 13 moves from the first switching position shown in FIG. 2 to the second switching position shown in FIG. 4, this main valve element 13 pushes the auxiliary valve element 33, seated on the auxiliary valve seat 34, through the stem 40. As a result, the auxiliary valve element 33 moves away from the auxiliary seat 34, and the auxiliary valve element 33 is displaced from the first switching position shown in FIG. . 3 to the second switching position shown in FIG. 5.

[0028] As shown in FIG. 3 and 5, the valve stem 40 is located in the inner space of the first plate 35 and the second plate 36 and is arranged to move in the direction of the axis L in this internal space. Further, on the outer peripheral surface of the stem 40, an annular flange 41 is formed, protruding radially outward from the drain 40. The annular flange 41 is provided with a sealing element 42 to maintain air tightness between the annular flange 41 and the surface of the inner wall of the second plate 36. The stem 40 is in sliding contact with the surface the inner wall of the second plate 36 and is configured to move in the direction of the axis L, supported by this surface of the inner wall.

[0029] The valve stem 40 comprises a first end and a second end, wherein the first end 40a is connected to the auxiliary valve element 33 through an opening in the annular auxiliary valve seat 34. Further, the second end 40b of the valve stem 40 projects into the intermediate communication hole 51 (second hole 52b) of the intermediate connecting section 50, which will be described later, through the opening 43a of the lid member 43, which is mounted on the opening of the auxiliary chamber 32 (right side in FIG. 3 )

[0030] Further, the stem return spring 44 is located on the first end 40a of the valve stem 40 so as to constantly press the stem 40 against the second end 40b (that is, the main valve member 13) which is opposite the first end 40a. The stem return spring 44 is formed as a cylindrical spring, one end of which abuts against the rear surface of the protrusion 35a of the first plate 35 (the surface opposite to the direction in which the auxiliary seat 34 of the valve protrudes), and the other end is inserted into the receptacle 45 located on the outer periphery 40 valve stem.

[0031] As shown in FIG. 2, when the auxiliary valve element 33 is in the first switching position, the annular flange 41 of the valve stem 40 is meshed with the peripheral edge of the hole 43a of the cover element 43, restricting the movement of the valve stem 40, which is spring-loaded, toward the main valve element 13. Here the first end 40a of the valve stem 40 is retracted from the auxiliary valve element 33 by a predetermined distance.

[0032] Further, the valve stem 40 includes an exhaust passage 46 connecting the auxiliary exhaust channel A2 to the atmosphere exhaust channel 55, which will be described later. As shown in FIG. 3 or 5, the exhaust passage 46 is formed by a first hole 46a located on the first end 40a of the rod 40 and open along the L axis, a second hole 46b located on the second end 40b of the rod and formed in a direction perpendicular to the L axis, and an intermediate passage 46c, extending in the direction of the L axis in the stem 40 and connecting the first and second openings 46a and 46b. Further, the second hole 46b is formed to communicate with the second through hole 52b of the intermediate connecting section 50 when the annular flange 41 is engaged with the hole edge 43a in the cover member 43 (see FIGS. 2 and 3).

[0033] As shown in FIG. 3, when the auxiliary valve element 33 is in the first switching position, the first end 40a of the valve stem 40 and the auxiliary valve element 33 are separated from each other, as described above. That is, the first hole 46 a of the rod 40 is open, and the exhaust passage 46 is in communication with the auxiliary exhaust channel A2. Accordingly, as shown by the arrow in FIG. 2, exhaust air from the auxiliary exhaust channel A2 flows through the interior of the first plate 35 into the first opening 46a of the valve stem 40 and flows through the intermediate passage 46c and the second opening 46b and is discharged into the atmosphere through the exhaust channel 55.

On the contrary, as shown in FIG. 5, when the auxiliary valve member 33 is in the second switching position, the auxiliary outlet channel does not communicate with the exhaust passage 46, since the first opening 46a of the valve stem 40 is closed by the end face of the auxiliary valve element 33.

[0034] Further, in this embodiment, as shown in FIG. 1 or 6, an intermediate connecting section is located between the first valve section 10 and the second valve section 30.

As shown in FIG. 2 or 4, the intermediate connecting section 50 comprises an elongated block 51 having a rectangular external shape, a through hole 52 formed in the block 51 and extending in the direction of the L axis and having a circular cross section, and a pusher 53 located in this through hole 52. A through hole 52 is aligned with the main chamber 12 of the first valve section 10 and the secondary chamber 32 of the second valve section 30 (ie, located on the L axis), and the main chamber 12 and the secondary chamber 32 are connected to each other through the hole 52. Next, through The second hole 52 has a first hole 52a that communicates with the main camera 12, and a second hole 52b that communicates with the secondary camera 32, while the diameter of the second hole 52b is smaller than the diameter of the first hole 52a. Accordingly, a step portion 54 is formed at the interface between the first hole 52a and the second hole 52b, which serves as a socket for the main return spring 16. Further, an atmosphere channel 55 is formed on the second hole 52b of the through hole 52.

[0035] As shown in FIG. 6, a thin plate-shaped gasket is installed between the housing 11 of the first valve section 10 and the block 51 of the intermediate connecting section 50, therefore, the main chamber 12 communicates with the through hole 52 through an opening 71 penetrating through the gasket 70 in the thickness direction.

[0036] As shown in FIG. 2-4, the pusher 53 has a substantially cylindrical shape extending in the L axis direction, and the first end 53a at one end in the L axis direction is connected to the second end 49b of the valve stem 40, and the second end 53b at the other end in the L axis direction with one end 13a of the main valve element 13. In other words, the pusher 53 is configured to indirectly connect the main valve element 13 and the auxiliary valve element 33.

Further, a circular recess 56 is formed on a substantially central axis (on the L axis) of the first end face 53a of the pusher 53. A second end 40 of the valve stem 40 is inserted into the recess 56. Additionally, the main return spring 19 is installed on the outer periphery of the pusher 53, surrounding its outer periphery.

[0037] Since the pusher 53 is located between the main valve element 13 and the auxiliary valve element 33, the second end 40 of the rod is supported by the peripheral wall of the recess 56, but does not contact the bottom 56a of the recess 56 of the pusher 53 when the main valve element 13 of the first valve section 10 is in first switching position. That is, when the main valve element 13 is in the first switching position, the force toward the auxiliary valve element 33 (left in FIG. 2) does not act on the stem 40, and the auxiliary element 33 is held in the first switching position.

[0038] Conversely, when the main valve element 13 is moved from the first switching position to the second switching position, the pusher 53 together with the main valve element 13 is shifted towards the auxiliary valve element 33. Accordingly, the second end 40b of the rod 40 abuts the bottom 56a of the recess 56 the pusher 53, and the valve stem 40 is pushed to the auxiliary valve element 33. As a result, the auxiliary valve element is seated on the auxiliary valve seat 34 in the auxiliary chamber 32, pushing etsya first end 40a of the valve stem 40 disposed at the opposite end, the auxiliary valve member 33 moves away from the auxiliary seat 34 and an auxiliary valve member moves into the second switching position.

[0039] As shown in FIG. 1 or 6, in the switching valve 1 according to the present utility model, a pair of brackets 60 is mounted on one end of the valve body 2 (on the left in FIG. 6) using a plurality of first and second fixing screws 65 and 66. As shown in FIG. 1 or 6, the bracket 60 is designed to integrally connect the first valve section 10 to the second valve section 30 and is made of a solid material, for example, a metal plate or a resin plate having an L-shape. In addition, the bracket 60 includes first connecting plates 61 attached to the block 51 of the intermediate connecting section 50 at the end 51a, which is opposite the second valve section 30, and second connecting plates 62 attached to both walls of the housing 31 of the second valve section 30 located in direction perpendicular to the axis L.

[0040] As shown in FIG. 1 and 6, the first connecting plate 61 has the shape of an elongated plate, the length of which is substantially equal to the length of the end face 51a in the longitudinal direction (vertical direction in FIG. 1). Further, the first connecting plate 61 has first fixing holes 63, 63 extending through the first connecting plate 61 in the thickness direction in the position at both ends in the longitudinal direction. On the other hand, the second connecting plate 62 is a plate part substantially perpendicularly extending from the longitudinal edge of the first connecting plate 61, with a pair of fixing holes 64, 64 made at the distal end in the direction of the L axis. Next, as shown in FIG. 6, a pair of screw holes 39, 39 are made in both walls of the body 31 of the second valve section 30 so that the first mounting screws 65 coincide with the screw holes 39, 39.

[0041] When the bracket 60 is used to connect the first valve section 10 and the second valve section 30, both walls of the housing 31 of the second valve section 30 are clamped by the second connecting plates 62 of the bracket 60 so that the second mounting holes 64, 64 formed in the second connecting plates 62 , aligned with the holes 39 for installing screws in the housing 31. In this state, the first mounting screws 65 are inserted externally into one of the brackets 60. Then, the brackets 60 are fastened with nuts 68 with washers 67 on the outside of the other bracket 60 for thereby connecting the pairs of brackets 60 and the housing 31 of the second valve section 30.

[0042] Then, the flat surface of the first connecting plate 61 of the bracket 60 is brought into contact with the end face 51a of the block 51 of the intermediate connecting section 50. Then, the first mounting holes 63 in the first connecting plate 61, the holes 57 for installing screws made at the corners of the block 51, and the holes 72 in the gasket 70 are aligned with each other and the second fixing screws 66 are inserted into the holes 63, 57 and 72. Then, an external thread (not shown in the drawings) cut at the distal ends of the second fixing screws 66 is screwed into the threaded holes 5 into orpuse 11 of the first section 10 of the valve. Thus, the first valve section 10 and the second valve section 30 are integrally connected. In the above example, the second connecting plate 62 and the housing 31 of the second valve section 30 are first connected. However, it is also possible to first connect the first connecting plate 61 to the first valve section 10.

[0043] In the switching valve 1 in the above configuration, when control air is not supplied to the second cylinder chamber 21b of the cylinder of the valve driving section 20 (OFF state), the main valve element 12 located in the main chamber 12 of the first valve section 10 is pressed by the force of the main return spring 19 towards the other end 13b of the main valve member 13, as shown in FIG. 2 and 3. Accordingly, the main section 14 of the main valve member 13 is located in a first switching position in which it abuts against the second main valve seat 17b. In this state, communication between the main inlet channel P1 of the first valve section 10 and the main outlet channel A1 is blocked, and the flow paths between the main outlet channel A1 and the main outlet channel R1 communicate with each other, therefore, compressed air from the main outlet channel A1, i.e., the exhaust air from the actuator is discharged into the atmosphere through the main exhaust channel R1.

[0044] When the main valve element 13 is in the first switching position, the first end face 53a of the pusher 53 (bottom 56a of the recess 56) connected to the main valve element 13 is not in contact with the second end 40b of the stem 40 in the second valve section 30, as shown in FIG. 3. Accordingly, the valve stem 40 is drawn by the force of the rod return spring 44 toward the main valve element 13, and the first end 40a of the rod 40 and the auxiliary valve element 33 are spaced apart from each other by a predetermined distance. As a result, the auxiliary valve element 33 is located in the first switching position in which it is seated on the auxiliary valve seat 34 in the auxiliary chamber 32 due to the force of the auxiliary return spring 38. When the auxiliary valve element 33 is in the first switching position, flow passages between the auxiliary inlet channel P2 of the second valve section 30 and the auxiliary exhaust channel A2 are blocked. In this case, as shown by the arrow in FIG. 2 or in FIG. 3, the exhaust air from the auxiliary exhaust channel A2 flows into the second opening 52b of the intermediate connecting section 50 through the exhaust passage 46, which is formed by the first opening 46a, the intermediate channel 46c and the second opening 46b, made in the valve stem 40, and is released into the atmosphere through the channel 55 release to the atmosphere.

[0045] In this state, when control air is not supplied to the second cylinder chamber 21b of the cylinder of the valve driving section 20 (ON state), the driving piston 23 is driven to the first cylinder chamber 21a. Accordingly, the main valve element 13 connected to the piston 23 moves to a position adjacent to one end 13a (toward the auxiliary valve element 33), counteracting the force of the main return spring 19, and the section 14 of the main valve element 13 is shifted to the second switching position in which it abuts against the first main valve seat 16 b (see FIG. 4). When the main valve element 13 is in the second switching position, the main inlet channel P1 and the main outlet channel A1 are in communication with each other, and the main outlet channel A1 and the main outlet channel R1 are isolated from each other.

[0046] Here, when the pusher 53 together with the main valve member 13 moves toward the auxiliary valve member 33, the bottom 56a of the recess 56 in the pusher 52 abuts against the second end 40b of the stem 40 (see FIG. 5). In this state, when the valve stem 40 moves in the direction of the auxiliary valve element 33, the bottom 56a of the recess 56 of the plunger 52 abuts against the second end 40b of the rod 40 (see FIG. 5). In this state, when the stem 40 moves toward the auxiliary valve element 33, overcoming the compressive force of the rod return spring 44, the distance between the first end 40a of the rod 40 and the auxiliary valve element 33 decreases.

[0047] When the distance between the first end 40a of the stem 40 and the auxiliary valve member 33 becomes zero, the force transmitted by the first end 40a of the stem 40 begins to act on the auxiliary valve element 33 fitted to the auxiliary valve seat 34, counteracting the force of the auxiliary return spring 28 As a result, the auxiliary valve element 33 moves to the second switching position, in which it is spaced from the auxiliary seat 34, and opens a message along the flow passages between the auxiliary inlet independent channels P2 and the auxiliary discharge channel A2. As shown by the arrow in FIG. 4, compressed air supplied from the auxiliary inlet channel P2 is discharged through the auxiliary exhaust channel A2.

As described above, when the main valve element 13 is shifted from the first switching position to the second switching position, the auxiliary valve element, the offset of which is synchronized, moves from the first switching position to the second switching position. Further, when the auxiliary valve member 33 is in the second switching position, the first hole 46a, which is open at the first end 40a, is closed since the first end 40a of the stem abuts against the auxiliary valve element 33. Accordingly, an outlet passage 46 formed in the valve stem 40 and auxiliary exhaust channel A2 are not communicated with each other.

[0048] In this state, when the supply of control air to the second cylinder chamber 21b of the cylinder of the valve driving section 20 is stopped (OFF state) and the control air in the second cylinder chamber 21b of the cylinder ends, the main valve element 13 of the first valve section 10 returns from the second switching position, shown in FIG. 4 to the first switching position shown in FIG. 2, under the action of the force of the main return spring 19.

Accordingly, the pusher 53 connected to the main valve element 13 moves with the main valve element 13 towards the main valve element 13 (to the right in FIG. 2), and the valve stem 40 is pressed against the main valve element 13 by the force of the stem spring 44, thereby, the stem 40 ceases to be pressed against the auxiliary valve element 33. Here, the annular flange 41 of the valve stem element 40 engages with the peripheral edge of the hole 47a of the cover element 47, thereby restricting movement towards the main the valve element 13. The auxiliary valve element 33 is configured to return to the first switching position in which it is struck by the auxiliary seat 34 under the action of the force of the auxiliary return spring 38.

As described above, when the main valve element 13 returns from the second switching position to the first switching position by the main return spring 19, the auxiliary valve element 33, which is synchronized with this movement, returns from the second switching position to the first switching position by the force of the auxiliary return spring 38.

[0049] As described above, in the switching valve 1 of the present embodiment, the main valve element 13 m, the auxiliary valve element 33 are arranged to synchronously move. Accordingly, for example, the switching position of the main valve element 13 in the first valve section 10 can be determined by directing compressed air leaving the auxiliary exhaust channel A2 in the second valve section 30 to a corresponding display device, for example, a pneumatic indicator. In addition, compressed air leaving the auxiliary exhaust channel A2 in the second valve section 30 can also be used to drive other actuators. Accordingly, the air leaving and the second valve section 30 can be selectively used depending on the situation. Moreover, since the first valve section 10 and the second valve section 30 have flow paths isolated from each other, one switching valve 1 is capable of switching two different flow paths.

[0050] The switching valve of the present utility model has been described above. However, the present application is not limited to the described option and various changes can be made to it, without going beyond the scope defined by the attached formula.

[0051] For example, in the illustrated embodiment, the first valve section 10 is a three-way valve and the second valve section 30 is a two-way valve. However, the number of paths is not limited. Further, the intermediate connecting section 50 is located between the first valve section 10 and the second valve section 30 so that the main valve element 13 indirectly communicates with the auxiliary valve element 33 through the plunger 53 of the intermediate connecting section 50. However, if the main valve element 13 and the auxiliary valve element 33 move synchronously, the main valve element 13 can be directly connected to the auxiliary valve element 33 without the use of a pusher 53.

List of items

[0052]

1 - switching valve

2 - valve body

10 - the first section of the valve

12 - main camera

19 - main return spring

20 - valve drive section

30 - second valve section

32 - auxiliary camera

38 - auxiliary return spring

40 - stock

46 - exhaust passage

55 - channel for release into the atmosphere

A1 - main exhaust channel

A2 - auxiliary exhaust channel

P1 - main inlet

P2 - auxiliary inlet

R1 - main exhaust channel

Claims (13)

1. A switching valve that switches the connection state between the plurality of channels that communicate with the main chamber due to the displacement of the valve element located in the main chamber, characterized in that it contains: a first valve section that switches the first flow passage containing a plurality of main channels, and a second valve section that switches the second flow passage containing a plurality of auxiliary channels and isolated from the first flow passage, a first valve section and a second valve section are located at one end and at the other end of the valve body, respectively; the first valve section includes a main chamber communicating with the main channels, a main valve element located in the main chamber and configured to switch connection states between the main channels, and a valve drive section that drives the main valve element; the second valve section includes an auxiliary chamber in communication with the auxiliary channels, and an auxiliary valve element located in the auxiliary chamber and configured to switch the connection states between the auxiliary channels; wherein the main chamber and the auxiliary chamber, and the main valve element and the auxiliary valve element, respectively, are located on the same axis; and the main valve element and the auxiliary valve element perform the switching operation synchronously. 2. The valve of claim 1, wherein the first valve section is a two-position valve in which the main valve element has a first switching position and a second switching position, and the second valve section is a two-position valve in which the auxiliary switching element has a first switching position and a second switching position, and is a two-way distributor having two channels, an auxiliary inlet channel and an auxiliary outlet channel. 3. Valve 1 or 2, wherein the main valve element and the auxiliary valve element are driven by the valve driving section when moving from the first switching position to the second switching position, and are driven by the return spring when moving from the second switching position to the first switching position. 4. Valve 1 or 2, in which an axially extending valve stem is disposed between the main valve member and the auxiliary valve member such that the main valve member and the auxiliary valve member are connected by a valve stem. 5. The valve according to claim 3, in which the valve stem extending in the axial direction is located between the main valve element and the auxiliary valve element so that the main valve element and the auxiliary valve element are connected by a valve stem. 6. The valve according to claim 4, wherein the valve stem has an exhaust passage formed therein, and the exhaust passage communicates with an auxiliary exhaust channel and an exhaust channel to the atmosphere that is open to the atmosphere. 7. The valve according to claim 5, wherein the valve stem has an exhaust passage formed therein, and the exhaust passage communicates with an auxiliary exhaust channel and an exhaust channel to the atmosphere that is open to the atmosphere.

Images