JPH03500505A - Discharge valve device for high viscosity media - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] Discharge valve device for high viscosity media The present invention relates to a discharge valve device for a highly viscous medium, and relates to a regulator of a valve body connected to a discharge port. The present invention relates to a discharge valve device having a discharge valve device.

A solution of a highly viscous medium discharged through a valve device is described, for example, in US Pat. No. 4,030,64 It is well known as 0.4156495.4474307 etc. Such solutions are Pressure can be increased by applying pressure inside the container through the condensation discharge pipe or by using a manual pump. It works by sending.

The main object of the present invention is to provide a useful discharge valve device of the kind described above, which is simple and convenient. Discharge valve system that can effectively and accurately interrupt dispensing A supply passage 7 for a fluid 8 is formed in a discharge valve device l having a valve 2 that provides a and high viscosity media3, such as adhesives, plastics, rubber, grease, food, etc. A regulator 4 that is used for effective and accurate discharge and adjusts the valve body 5 This regulator is capable of closing the discharge port 6. the fluid 8 is guided to the discharge port 6 via the supply passage 7, but at this time, the highly viscous medium 3 is collected. , is suitably discharged into the valve body 5 while being isolated from the storage chamber 9 that contains the liquid. Specific examples and As shown, the supply passage 7 is formed inside the actuator rod 10, This actuator rod 10 is attached to the valve body 5, and one end 10A is for fluid storage. The other end 10B faces the part 5A of the valve body facing the discharge port 6. . The fluid storage chamber 11 contains compressed air, compressed gas, compressed liquid, and other compressed fluids. 8 is accommodated.

The actuator rod 10 has a hole 12 formed in the regulator 4 at one end thereof. The piston 13 is fixed to the cylinder 14A. It is formed to correspond to the cylinder chamber 14 and is accommodated therein, and the fluid 8 is further contained in the accommodation chamber 11. It is now possible for an influx to occur. This actuator rod 10 is It is constructed so that it can be actuated by two springs 15, 16 that act independently of each other. has been completed. These springs 15 and 16 are compression coil springs, and are active springs. It is provided to be slidable with respect to the tuator rod 10, and one side is appropriately positioned relative to the other. One spring is adapted to apply a large load to the actuator rod 10. are combined. In other words, if the valve regulator 4 is not operating, high viscosity Valve 2 is set so that medium 3 is not discharged! It is necessary to move to the rIJ and occlude it. Therefore, the spring 15 is configured to act under a large load F, and It is preferable to guide the valve body 5 into contact with an annular sealing surface 17 formed at the discharge port 6. Delicious. Of course, for the purposes of the present invention, loads other than this load must also be considered. Needless to say, it won't happen.

The highly elastic spring 15 acts between the valve body 5 and the fixed stopper 18. On the other hand, the low elasticity spring 16 is provided between the defining stop 19 and the moving stop. 20. This moving stopper 20 is activated. For example, the ring 20 is attached to the actuator rod 10, and the actuator is provided so as to be able to freely slide on the data rod 10 and come into contact with the seal 21. ing. This seal 21 is a space located around the actuator rod 10. 22, the spring 16, and the fluid storage chamber 11. An O-ring 21B is installed in the recess 23 of the partition wall 24 located between the two spaces 11 and 22. It is preferable to configure it with a girder sleeve 21A.

The piston 13 constitutes a part of the regulator 4, and is directed in the direction of arrow "25" in FIG. It is now possible to move to

Then, the valve body 5 is moved to the open position i rII via the actuator rod 10 described above. Move to J. For example, the piston 13 has a magnetic core disposed around the piston 13. It is configured to generate electromagnetism by the coil 26 and to be operated by this.

The supply passage 7 is configured so that the input lower A can be closed, so that supply can be prevented. ing. Specifically, the compression seal body 27 (preferably an O-ring) is It is configured to be accommodated in a sealing seat 28 on the outer peripheral surface 13A of the piston 13.

There is a predetermined gap between the outer circumferential surface 13A of the piston 13 and the inner circumferential surface of the cylinder 14A. A gap 29 is formed so that the fluid 8 freely flows from the space 11 into the cylinder chamber 14. It is now possible to do so.

It is preferable that the housing 30 is provided with a plurality of valves 2. There are storage chambers 11 and 9 for high viscosity fluid 3 and compressed fluid 8, and each valve device is mutually connected. Although they operate independently, they constitute a common housing chamber for each valve 2.

As shown in FIG. It is constructed so that it can be moved in a certain relationship.

By making the valve device 1 have a structure that can accommodate and accumulate the medium 3 such as air bubbles, The medium 3 to be discharged from the valve 2 can be applied intermittently.

The function of the valve device 1 can be understood from the above discussion and drawings, but this function will be summarized below. For example, the compressed air 8 has a discharge port 6 closed to the valve body 5 by a spring 15. When the supply passage 7 is blocked, the regulator 4 acts and the supply passage 7 is blocked.

For this reason, the piston 13 moves to the top dead center, that is, the magnet 26 acts. and rises against counter pressure 32.

As a result, the seal 27 is sealed and no more air, etc. It is designed not to lead to Air etc. 8 discharged from the discharge lower B of the supply passage 7 forms a large amount of bubbles in the highly viscous medium 3, although the medium 3 is compressed. Instead, this medium 3 is discharged from the discharge port 6. As a result, from the discharge port 6 A desired amount of high viscosity medium 3 can be intermittently discharged. Effectively, media 3 is intermittent The last thing to leave the outlet 6 before it becomes occluded is air bubbles or the like. this is , compared to conventional equipment, even when applying adhesive etc. to the application surface continuously, This was considered difficult with conventional devices, but with this device, it is possible to continue with interrupted media for a long time. This shows the advantage of being able to perform thin coatings. Release of magnet 26 As a result, the valve body 5 moves from the open position (2) to the closed position (4).

It should be noted that the present invention is not limited to the above-mentioned embodiments, and may go beyond the gist of the present invention. Various modifications can be made unless otherwise specified.

international search report lmenv+m+yl　^*#ca+na　NIL,　PCT　/S　=a　 8/00501

Claims (1)

[Claims] 1. High viscosity medium with regulator (4) of valve body (5) in contact with discharge port (6) In the body discharge valve device (1), the fluid supply passage is isolated from the storage chamber (9). (7) is guided to the discharge port (6), and air bubbles etc. are accommodated and stored in the medium (3). Thus, intermittent application of the supply passage is achieved by the medium (3) being applied from the valve (2). A discharge valve device for a highly viscous medium, characterized in that: 2. The fluid supply passage (7) faces the valve body (5) and is discharged by the regulator (4). A closed position (I) that closes the sealing surface (17) of the outlet (6) and a position that is separated from the discharge port (6). Claim 1, characterized in that the device moves between an open position (II) between The high viscosity medium discharge valve device as described in 2. 3. The fluid supply passage (7) is connected to an actuator rotor housed in the valve body (5). is formed inside the head (10) and faces the discharge port (6) from the fluid storage chamber (11). Claim 2, characterized in that it is formed up to a part of the valve body (5). A discharge valve device for a highly viscous medium according to. 4. The fluid storage chamber (11) may contain compressed air, compressed gas, or compressed liquid. A discharge valve device for a highly viscous medium according to claim 3, characterized in that: 5. The fluid supply passageway (7) can be closed by the regulator (4). A discharge valve device for a highly viscous medium according to claims 3 to 4, characterized in that: . 6. Said regulator (4) has a piston (13) and has a valve device in an open position ( In II), the patent is characterized in that the supply of fluid to the discharge port (6) is stopped. A discharge valve device for a highly viscous medium according to claim 5. 7. The piston (13) is characterized in that it is operated by a magnet (26). A discharge valve device for a highly viscous medium according to claim 6. 8. The compressed sealing material (27) is inside the regulator (4) and is located in the fluid supply passageway (7). ) is provided in the population (7A), preferably an O-ring. A discharge valve device for a highly viscous medium according to claims 5 to 7. 9. The valve body (5) preferably bears a load ( F), the discharge port (6) is moved to the closing position (I) where the discharge port (6) is closed. A discharge valve device for a highly viscous medium according to claims 1 to 8. 10. A plurality of valve devices (2) are provided in the housing (30), the housing ( 30) includes a medium (3) and a fluid (8) common to the plurality of valve devices (2). It is characterized in that the storage chambers (9, 11) are provided so as to act independently of each other. A discharge valve device for a highly viscous medium according to any one of claims 1 to 9.