JP2021023920A - Liquid coating module - Google Patents

Abstract

To provide a liquid coating module enabling visually confirming whether a mechanism of suppressing dripping of liquid is operated or not, and capable of securely suppressing dripping of liquid.SOLUTION: A liquid coating module includes: (A) a housing 11 having an inner part of a cylindrical member as a flow passage 41 to circulate liquid, and an outflow passage 45 extending from the flow passage 41 to an edge face 21A at one side in an axial direction, and making liquid flow out from the flow passage 41; (B) a movable body 12 stored inside the housing 11, and made movable between a position of closing the outflow passage 45, and a position of opening the outflow passage 45; and (C) a nozzle member 13 externally fitted to an end part at one side of the housing 11 (second cylinder member 21) and slidably provided in an axial direction, and having a discharge passage 62 for discharging liquid outflowing from the outflow passage 45 to the outside of the liquid coating module.SELECTED DRAWING: Figure 2

Description

The present invention relates to a liquid coating module for coating a liquid.

The following Patent Document 1 describes an adhesive supply device for applying an adhesive as a liquid coating module. In the device described in Patent Document 1 below, (A) a housing having a supply port provided on the bottom surface and containing an adhesive inside, and (B) an upper end surface surrounding the supply port of the housing and extending downward. A nozzle attached to the bottom of the housing so as to be able to move up and down, and a valve body that is arranged so as to be able to move up and down in the nozzle (C) so as to close the supply port by ascending and open the supply port by descending. It is supposed to be equipped with. The device described in Patent Document 1 below uses a so-called sackback method, and by retracting the valve body, the pressure of the adhesive inside the nozzle is reduced, and the adhesive drips from the tip of the nozzle. It suppresses that.

Jikkenhei 7-31167

When the sackback is used to suppress the dripping of the liquid as in the device described in Patent Document 1, the required pull-in amount of the valve body depends on the viscosity of the liquid, the opening area of the nozzle tip (the area of the discharge port), and the like. Is different. However, for example, even if the nozzle is replaceable or can be used for applying various liquids, it is difficult to adjust the pull-in amount of the valve body existing inside the housing, and the valve body can be sufficiently used. It may not be possible to pull in. Further, since the valve body exists inside the housing, it is not possible to confirm whether or not the valve body is properly pulled in.

The present invention has been made in view of such circumstances, and it is possible to visually confirm whether or not the mechanism for suppressing the dripping of the liquid has operated, and it is possible to reliably suppress the dripping of the liquid. It is an object of the present invention to provide a liquid coating module capable of providing a liquid coating module.

In order to solve the above problems, the liquid coating module of the present invention
A liquid application module for applying liquid,
It is a tubular member whose inside is a flow path for flowing a liquid, and extends from an inflow path for flowing the liquid into the flow path and an end face on one side in the axial direction from the flow path, and the liquid flows out from the flow path. A housing with an outflow path to allow
A movable body that is at least partially housed inside the housing and is movable between a position that blocks the outflow path and a position that opens the outflow path.
A nozzle member that is fitted on one end of the housing and is slidably provided in the axial direction, and has a discharge path for discharging the liquid flowing out from the outflow path to the outside of the liquid coating module.
It is characterized by being equipped with.

In the liquid coating module having this configuration, the nozzle member is slidable in the axial direction with respect to the housing, and by moving the nozzle member to one side with respect to the housing, the nozzle member is moved to one end surface of the housing. Can be separated from. In the liquid coating module having this configuration, the nozzle member may be manually operated or may be operated by a device having a drive source. Then, when the outflow path is blocked by the movable body, the liquid coating module having this configuration manually or automatically moves the nozzle member to one side with respect to the housing and separates it from the end face on one side of the housing. Therefore, the pressure in the space between the housing and the nozzle member can be reduced (negative pressure). Therefore, the liquid coating module having this configuration can suck the liquid remaining in the discharge path of the nozzle member into the space between the housing and the nozzle member, and reliably suppresses the liquid from dripping from the discharge path. can do. Since one side of the housing is the tip side (front side) where the liquid coating module discharges the liquid, in the following description, moving the nozzle member to one side is to move forward and to the other side. May be called retreat.

Since the liquid coating module having this configuration operates the nozzle member arranged on the outside of the housing to suppress the liquid from dripping, it is possible to easily secure the amount of movement in the direction in which the nozzle member is advanced. It is possible to surely suppress the dripping of the liquid. Further, according to the liquid coating module having this configuration, the operation of the nozzle member can be easily visually confirmed. Further, according to the liquid coating module having this configuration, it is possible to manufacture the nozzle member in accordance with the existing liquid coating module and retrofit the nozzle member.

The movable body included in the liquid coating module having this configuration is not particularly limited in its configuration, and even if it is configured to close the opening on the flow path side of the outflow path, it is configured to close the opening to one end surface of the outflow path. You may. For example, when the movable body is housed inside the housing and slidable in the axial direction, the movable body is moved forward to close the opening on the flow path side of the outflow path, or is retracted. It may be configured to close the opening to one end face of the outflow path.

In the above configuration, a nozzle moving mechanism for moving the nozzle member in the axial direction is provided, and when the nozzle moving mechanism moves from a position where the movable body opens the outflow path to a position where the outflow path is blocked, The nozzle member may be configured to move to the one side in the axial direction.

In the liquid coating module having this configuration, the nozzle member is automatically advanced by the nozzle moving mechanism at the timing when the movable body blocks the outflow path, so that the liquid dripping can be suppressed more reliably. The structure of the nozzle moving mechanism is not particularly limited, and for example, the nozzle member may be moved by using air pressure or a driving force of a motor or the like. Further, for example, when the liquid coating module is a hand gun type, the nozzle member may be moved by linking with the operation of the operating member operated by the user.

Further, in the above configuration, the movable body extends along the axial direction of the housing so as to be movable in the axial direction, and the flow of the outflow path at a position moved to the one side in the axial direction. The liquid coating module has a shaft shape that closes the opening on the road side, and the liquid coating module resists the urging member that urges the movable body toward the one side in the axial direction and the urging force of the urging member. A movable body retracting mechanism for retracting the movable body to the other side in the axial direction may be provided.

The liquid coating module having this configuration is configured to close the opening of the outflow path to the flow path side by advancing the movable body. In the liquid coating module having this configuration, since the movable body does not protrude from the tip of the housing to the outside, the nozzle member can be easily attached to the end on one end side of the housing.

Further, in the above configuration, the nozzle member is formed so that the inner surface is in contact with the one-sided end surface of the housing, and the inner surface of the nozzle member is in contact with the one-sided end surface of the housing. In the state, the discharge path may be configured to communicate with the outflow path.

The liquid coating module having this configuration is configured such that the housing and the nozzle member are in close contact with each other when the movable body opens the outflow path. Therefore, according to the liquid coating module having this configuration, the liquid remaining from the point where the movable body is closed to the downstream side, that is, from the opening of the outflow path to the flow path side to the tip of the nozzle (opening to the outside of the discharge path). The amount can be suppressed, and the distance for advancing the nozzle member in order to suppress dripping can be reduced.

Further, in the above configuration, the nozzle member may be detachable from the housing, and the flow path area of the outflow path may be larger than the flow path area of the discharge path.

The liquid coating module having this configuration can be changed to a nozzle member having a different discharge path flow path area within the range below the flow path area of the outflow path, and the discharge amount from the liquid coating module can be changed. It becomes.

Further, in the above configuration, a contact portion that the nozzle member contacts when moving to the one side, a contact portion holder that holds the contact portion in a changeable position in the axial direction, and a contact portion holder. It is also possible to have a configuration provided with a stopper mechanism for restricting the movement of the nozzle member to the one side.

In the liquid coating module having this configuration, the amount of advance of the nozzle member can be adjusted by adjusting the position of the contact portion, and the nozzle member can be adjusted according to the liquid to be coated, the flow path area of the discharge path, and the like. The amount of advance can be easily optimized.

According to the present invention, it is possible to visually confirm whether or not the mechanism for suppressing the dripping of the liquid has been operated, and to provide a liquid coating module capable of surely suppressing the dripping of the liquid. Can be done.

It is a side cross section of the adhesive coating head which is the liquid coating module of the first embodiment of the present invention. It is a cross-sectional view which shows the vicinity of the nozzle shown in FIG. 1 enlarged, and is the figure which shows the state which closed the outlet. It is a cross-sectional view which shows the vicinity of the nozzle shown in FIG. 1 enlarged, and is the figure which shows the state which opened the outlet. It is a side cross section of the adhesive coating gun which is the liquid coating module of the second embodiment of the present invention.

Hereinafter, as a mode for carrying out the present invention, some examples of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the following examples, and can be carried out in various embodiments with various modifications and improvements based on the knowledge of those skilled in the art.

The liquid coating module of the first embodiment of the present invention is shown in FIG. The liquid coating module of the first embodiment is an adhesive coating head 10 provided in an adhesive coating device for coating hot melt as a liquid, and ON / OFF of the adhesive by the adhesive coating head 10 is an adhesive. It is controlled by a control device included in the coating device. As shown in FIG. 1, the adhesive coating head 10 includes a generally tubular head main body 11 that functions as a housing, a shaft-shaped needle 12 as a movable body housed inside the head main body 11, and the like. It is configured to include a nozzle member 13 attached to one end side (lower side) of the head body portion 11 to discharge hot melt. In the following description, the side (one end side) on which the nozzle member 13 is attached and the hot melt is discharged may be referred to as the front side, and the opposite side (the other end side) may be referred to as the rear side.

The head main body 11 is generally composed of three tubular members, a first cylinder member 20, a second cylinder member 21, and a third cylinder member 22. The first cylinder member 20 has a hollow portion 26 having a circular cross section. The rear end of the second cylinder member 21 is fitted into the hollow portion 26 from the lower side, and the first cylinder member 20 and the second cylinder member 21 are integrated. Further, the second cylinder member 21 is also a member having a generally cylindrical shape and has a hollow portion 27. Further, a third cylinder member 22 is connected to the upper side of the first cylinder member 20, and the hollow portion 28 of the third cylinder member 22 is in a state of communicating with the hollow portion 26 of the first cylinder member 20. ing. The center line of the hollow portion 26, the center line of the hollow portion 27, and the center line of the hollow portion 28 are coaxially arranged, so that a through hole extending in the front-rear direction is formed in the head main body portion 11. It is in a state of being.

The needle 12 is housed in the head body 11 described above. Inside the head body portion 11, more specifically, inside the first cylinder member 20, a partition portion 20A having an inner diameter slightly larger than the outer diameter of the needle 12 and partitioning the hollow portion 26 back and forth is provided. .. That is, the hollow portion 26 has a front hollow portion 26A formed on the front side of the partition portion 20A and a rear hollow portion 26B formed on the rear side of the partition portion 20A.

The lower portion of the needle 12 is inserted into the hollow portion 27 of the second cylinder member 21, the upper end thereof is located in the rear hollow portion 26B, and the needle 12 is slidably arranged in the rear hollow portion 26B. It is fixed to the piston 30. Further, the needle 12 is arranged so that the axis is coaxial with the center line of the hollow portions 26 and 27, and is slidable along the axis with respect to the head main body portion 11.

Further, an adjustment knob 31 is arranged on the upper side of the third cylinder member 22. Specifically, the configuration is such that a screw is screwed between the inner peripheral surface of the third cylinder member 22 and the outer peripheral surface of the adjustment knob 31, and the adjustment knob 31 is in the axial direction (up and down) with respect to the third cylinder member 22. The position of the direction) can be adjusted. A compression coil spring 32, which is an urging member, is arranged between the adjustment knob 31 and the piston 30, and the compression coil spring 32 keeps the piston 30 and the needle 12 on the lower side (one side) at all times. It is being urged toward the side). Incidentally, although detailed description is omitted, the adhesive coating head 10 has a configuration in which the discharge amount of hot melt can be adjusted by adjusting the contraction amount of the compression coil spring 32 with the adjustment knob 31. ..

The first cylinder member 20 is formed with a communication passage 40 that communicates with the front hollow portion 26A from the outside. The communication passage 40 is connected to an externally arranged hot melt supply device by a hose, and is an inflow path for hot melt to flow into the inside of the adhesive coating head 10. That is, in the adhesive coating head 10, the front hollow portion 26A of the first cylinder member 20 and the hollow portion 27 of the second cylinder member 21 form a flow path 41 through which hot melt flows. A seal member 42 is arranged at the front end of the rear hollow portion 26B, and the flow path 41 is in a liquid-tight state.

As shown in FIGS. 2 and 3, the hollow portion 27 of the second cylinder member 21 has a tapered portion 44 whose inner diameter becomes smaller toward the lower end on the lower end side, and a tapered portion 44 extending downward from the tip of the tapered portion 44. It has an outflow path 45 that opens to the lower end surface (one end surface) 21A of the two cylinder members 21 and allows hot melt to flow out from the flow path 41. On the other hand, the tip portion 12A of the needle 12 is formed in a hemispherical shape, and when the needle 12 is moved downward (one side in the axial direction) by the compression coil spring 32, the tip portion 12A is moved to the second side. It comes into contact with the tapered portion 44 in the cylinder member 21. That is, the needle 12 is in a state in which the outflow path 45 is closed, more specifically, in a state in which the opening of the outflow path 45 on the flow path 41 side is closed.

Further, the first cylinder member 20 is formed with a communication passage 50 that communicates with the rear hollow portion 26B from the outside. The communication passage 50 is connected to an air pump arranged outside, and serves as an air supply path for supplying air to an air chamber formed by a piston 30 in the rear hollow portion 26B. Then, when the air is supplied from the communication passage 50, the pressure in the air chamber rises, and the piston 30 is moved upward against the urging force of the compression coil spring 32. That is, the needle 12 fixed to the piston 30 is retracted, and the outflow path 45 is opened. Therefore, in the adhesive coating head 10, an air cylinder 51 is formed including the first cylinder member 20, the third cylinder member 22, the piston 30, and the like, and the air cylinder 51 is a movable needle. It functions as a movable body retracting mechanism that retracts the 12 against the urging force of the compression coil spring 32.

By the way, in the state where the outflow passage 45 is blocked, the liquid pressure in the flow path 41 is made higher than the outside air pressure by the hot melt pumped from the supply device. Therefore, when the needle 12 is retracted by receiving the supply of air, the hot melt flows out from the gap between the tapered portion 44 and the needle 12 through the outflow path 45.

A nozzle member 13 is attached to the tip (one end) of the second cylinder member 21. As shown in FIGS. 2 and 3, the nozzle member 13 covers a tubular main body 60 having an inner diameter slightly larger than the outer diameter of the tip of the second cylinder member 21 on the upper side and a lower end side of the main body 60. A lid portion 61 and a nozzle portion 63 having a discharge path 62 formed so as to project downward from the center of the lid portion 61 and formed to penetrate in the axial direction are included. The nozzle member 13 is fitted onto the tip of the second cylinder member 21. An O-ring 64, which is a sealing member, is arranged on the outer peripheral surface of the tip of the second cylinder member 21, and the nozzle member 13 slides with respect to the second cylinder member 21 by the O-ring 64. It is possible.

As shown in FIG. 3, when the nozzle member 13 is moved (retracted) to the uppermost position with respect to the second cylinder member 21, the upper surface (inner surface) 61A of the lid portion 61 becomes the lower end surface 21A of the second cylinder member 21. And are in contact with each other without any gaps. Further, in that state, the discharge path 62 of the nozzle member 13 is in a state of communicating with the outflow path 45 of the second cylinder member 21. That is, by setting the nozzle member 13 to retract while the outflow passage 45 is open, the hot melt is smoothly discharged through the outflow passage 45 and the discharge passage 62.

On the other hand, as shown in FIG. 2, when the nozzle member 13 is moved downward (advanced) with respect to the second cylinder member 21, the upper surface (inner surface) 61A of the lid portion 61 becomes the lower end surface of the second cylinder member 21. It will be separated from 21A and a gap will be created between them. Then, when the needle 12 is advanced from the state shown in FIG. 3 to close the outflow passage 45, hot melt is left in the outflow passage 45 and the discharge passage 62. At this time, when the nozzle member 13 is advanced, the space S formed by the nozzle member 13 and the second cylinder member 21 becomes a negative pressure, and the hot melt left in the discharge path 62 becomes the space S. It is sucked in. Therefore, the adhesive coating head 10 can prevent the hot melt from dripping from the discharge path 62.

In the adhesive coating head 10, the nozzle member 13 is moved in the axial direction by the nozzle moving mechanism 70. The nozzle moving mechanism 70 is mainly composed of a pin cylinder 71. The pin cylinder 71 includes a cylinder 72, a piston 73 slidably housed inside the cylinder 72, and a piston rod 74 having one end fixed to the piston 73 and the other end protruding downward from the cylinder 72. , A compression coil spring 75 housed inside the cylinder 72 and urging the piston 73 downward. The cylinder 72 is fixed to the second cylinder member 21, and the piston rod 74 is fixed to the flange portion 13A of the nozzle member 13. As the pin cylinder 71 expands and contracts, the nozzle member 13 becomes the second cylinder member. Moved relative to 21. Further, the cylinder 72 is provided with an air supply path 72A so that air can be supplied from the air pump. The air supply path 72A is provided corresponding to the air chamber 76 formed on the lower side of the piston 73 in the cylinder 72.

That is, when air is supplied to the air chamber 76, the nozzle member 13 can be retracted by moving the piston 73 upward, and the piston 73 is moved downward by removing the air from the air chamber 76. It is possible to advance the nozzle member 13. It should be noted that the supply of air to the head body 11 for retracting the needle 12 and the supply of air to the pin cylinder 71 for retracting the nozzle member 13 may be performed in common at the same time. The adhesive coating head 10 can be controlled independently, and the nozzle member 13 can be advanced at a more appropriate timing.

Further, the adhesive coating head 10 is provided with a stopper mechanism 80 for restricting the advancement of the nozzle member 13. The stopper mechanism 80 is located below the flange portion 13A of the nozzle member 13, and has a contact portion 81 that the flange portion 13A contacts when the nozzle member 13 advances, and a contact portion that holds the contact portion 81. It is composed of a bracket 82 as a holding body. The bracket 82 is fixed to the cylinder 72 of the pin cylinder 71 in a state of extending downward. The contact portion 81 is composed of an adjusting screw 81A and an elastic material 81B attached to the tip of the adjusting screw 81A, and the adjusting screw 81A is screwed into a female screw hole formed in a shape extending in the vertical direction at the tip of the bracket 82. It is held in a matched state. From such a configuration, the contact portion 81 changes the position of the elastic material 81B by adjusting the vertical position of the adjusting screw 81A with respect to the bracket 82, and changes the position for restricting the advancing nozzle member 13. You can do it.

The adhesive coating head 10 configured as described above is liquid by operating a nozzle member 13 arranged on the outside of the head main body 11 which is a housing, specifically, on the outside of the second cylinder member 21. Since the configuration is such that the dripping of the liquid is suppressed, the amount of movement in the direction in which the nozzle member 13 is advanced can be easily secured, and the dripping of the liquid can be reliably suppressed. Further, the adhesive coating head 10 can easily visually confirm the operation of the nozzle member 13, and can surely suppress the dripping of the liquid.

Further, in the adhesive coating head 10, as shown in FIG. 3, the flow path area of the outflow path 45 of the second cylinder member 21 is larger than the flow path area of the discharge path 62 of the nozzle member 13. The nozzle member 13 is easily attached to and detached from the second cylinder member 21. From such a configuration, for example, by preparing nozzle members having different flow path areas of the discharge path within the flow path area of the outflow path 45 and replacing the nozzle members, the hot melt discharge amount can be easily changed. It becomes possible to do.

In the present adhesive coating head 10, the distance for advancing the nozzle member 13 required to prevent the nozzle member 13 from dripping from the discharge path 62 differs depending on the viscosity of the adhesive to be discharged. Since the adhesive application head 10 can adjust the advancing distance of the nozzle member 13 by the stopper mechanism 80, the advancing amount of the nozzle member 13 can be easily adjusted according to the viscosity of the adhesive. , The dripping of the liquid can be surely suppressed.

The liquid coating module of the second embodiment of the present invention is shown in FIG. The liquid coating module of the second embodiment, like the liquid coating module of the first embodiment, applies hot melt as a liquid, but is a hand gun type adhesive coating gun 100. The adhesive coating gun 100 receives a supply of hot melt that has been heated and melted from a supply device, switches ON / OFF of the hot melt discharge, and adjusts the hot melt discharge amount. .. Since the adhesive coating gun 100 has a configuration similar to that of the adhesive coating head 10 according to the first embodiment, the same components are used with the same reference numerals, and the description thereof will be omitted or simplified. Assumed to be performed.

Similar to the adhesive coating head 10 according to the first embodiment, the adhesive coating gun 100 has a generally tubular gun body 101 that functions as a housing and a movable body that is slidable with respect to the gun body 101. The needle 102 and the nozzle member 13 attached to one end side (left side in FIG. 4) of the gun main body 101 are provided. However, the movable body retracting mechanism of the adhesive coating head 10 according to the first embodiment is configured to retract the needle 12 by air pressure mainly with the air cylinder 51, but the movable body provided with the adhesive coating gun 100 is provided. It is different from the retreat mechanism. The movable body retracting mechanism included in the adhesive coating gun 100 is configured such that the operator manually retracts the needle 102 (depending on the force of the operator), and as shown in FIG. The adhesive coating gun 100 is different from the adhesive coating head 10 according to the first embodiment in the configuration of the rear side portion (the portion opposite to the nozzle member 13 and the right portion in FIG. 4).

In the adhesive coating gun 100, the gun body 101 is composed of a first cylinder member 110 and a second cylinder member 21, and the other end side (rear end side) of the first cylinder member 110 is used by an operator. The grip portion 111 to be gripped is fixed. The second cylinder member 21 is the same as the adhesive coating head 10 of the first embodiment, is fitted to one side (front side) of the first cylinder member 110, and is fitted to one side (front side) of itself. The nozzle member 13 is attached.

Similar to the adhesive coating head 10 of the first embodiment, the first cylinder member 110 is divided into a front hollow portion 112A and a rear hollow portion 112B, which are two spaces inside, by a partition portion 110A. Then, the front hollow portion 112A causes the hot melt flowing in from the inflow passage 40 to flow toward the outflow passage 45 by the hollow portion 27 of the second cylinder member 21, similarly to the adhesive coating head 10 of the first embodiment. The flow path 41 is formed.

The grip portion 111 closes the rear hollow portion 112B of the first cylinder member 110 and is connected to the rear end of the first cylinder member 110. The grip portion 111 includes a body portion 120 that constitutes the body of the adhesive coating gun 100 together with the gun main body portion 101, a grip portion 121 that extends downward from the body portion 120 and is gripped by an operator, and a body. It is configured to include a trigger 123 that is oscillatingly held around a rotation shaft 122 provided in the portion 120. The needle 102, in which the front side portion is inserted into the gun main body portion 101, is in a state in which the rear side portion is held by the body portion 120 of the grip portion 111.

A spring receiving member 125 is fixed to a portion located in the rear hollow portion 112B of the needle 102, and an urging member is formed between the spring receiving member 125 and the front surface of the body portion 120 of the grip portion 111. The compression coil spring 126 is coaxially arranged with the needle 102. The compression coil spring 126 always urges the needle 102 forward.

Further, the needle 102 is inserted through the through hole 123A of the trigger 123, and a contact portion 127 with which the rear end surface of the trigger 123 abuts is provided behind the trigger 123 in the needle 102. That is, when the trigger 123 is pulled backward by the operator, the needle 102 is moved toward the rear side. From such a configuration, in the present adhesive coating gun 100, the grip portion 111 is a movable body that retracts the needle 102, which is a movable body, against the urging force of the compression coil spring 126 by an operation input of an operator or the like. It functions as a retreat mechanism.

In the adhesive coating gun 100, the nozzle moving mechanism 130 for moving the nozzle member 13 in the axial direction is different from the nozzle moving mechanism 70 included in the adhesive coating head 10 of the first embodiment. The nozzle moving mechanism 130 included in the adhesive coating gun 100 is a link mechanism that links the operation of the nozzle member 13 to the operation of the trigger 123, and one end is connected to the trigger 123 and the other end is the flange portion of the nozzle member 13. The main component is the link 131 connected to the 13A. That is, in the adhesive coating gun 100, when the trigger 123 is pulled by the operator, the movable needle 102 and the nozzle member 13 are retracted, and when the operator releases the trigger 123, the compression coil spring 126 As the needle 102 is advanced, the needle 102 is returned and the nozzle member 13 is also advanced.

Therefore, in the adhesive coating gun 100 as well, similarly to the adhesive coating head 10 of the first embodiment, the hot melt left in the discharge path 62 is placed in the space between the nozzle member 13 and the second cylinder member 21. It is possible to prevent the hot melt from being sucked in and dripping from the discharge path 62.

<Other embodiments>
The liquid coating modules of the above two embodiments are provided with a nozzle moving mechanism, and the nozzle member 13 is automatically advanced in accordance with the timing of blocking the outflow path by the movable body. However, the liquid coating module of the present invention Does not have to be provided with a nozzle moving mechanism. That is, the structure may be such that the operator manually moves the nozzle member 13.

Further, the movable body is not limited to a shaft-shaped one, and may be able to switch between a state in which the opening of the outflow path to the flow path side or an opening of the outflow path to the outside of the housing is closed and open. Just do it. For example, the operation of the movable body is not particularly limited as long as the movable body can be seated and detached from the valve seat formed by the opening edge of the outflow path.

The liquid coating modules of the two examples described above are for applying a hot melt adhesive as a liquid, but the present invention is not limited to this, and the present invention uses various liquids such as other liquid agents and liquids such as ink. It can be used for coating modules.

10 ... Adhesive coating head [liquid coating module], 11 ... Head body [housing], 12 ... Needle [movable body], 13 ... Nozzle member, 20 ... 1st cylinder member, 21 ... Second cylinder member, 21A ... Lower end surface (one end surface), 22 ... 3rd cylinder member, 26 ... Hollow part (1st cylinder member), 26A ... Front hollow part, 26B ... Rear hollow part, 27 ... Hollow part (2nd cylinder member) , 28 ... Hollow part (third cylinder member), 30 ... Piston, 32 ... Compression coil spring [Bending member], 40 ... Communication passage [Inflow path], 41 ... Flow path, 45 ... Outflow path, 51 ... Air cylinder [Movable body retracting mechanism], 60 ... Main body, 61 ... Lid, 61A ... Top surface (inner surface of nozzle member), 62 ... Discharge path, 63 ... Nozzle, 64 ... O ring, 70 ... Nozzle movement mechanism, 71 ... Pin cylinder, 80 ... Stopper mechanism, 81 ... Contact part, 82 ... Bracket [contact part holder], 100 ... Adhesive coating gun [Liquid coating module], 101 ... Gun body [housing], 102 ... Needle [ Movable body], 110 ... 1st cylinder member, 111 ... Grip part [movable body retracting mechanism], 123 ... Trigger, 126 ... Compression coil spring [urging member], 130 ... Nozzle moving mechanism, 131 ... Link

Claims (6)

A liquid application module for applying liquid,
It is a tubular member whose inside is a flow path for flowing a liquid, and extends from an inflow path for flowing the liquid into the flow path and an end face on one side in the axial direction from the flow path, and the liquid flows out from the flow path. A housing with an outflow path to allow
A movable body that is at least partially housed inside the housing and is movable between a position that blocks the outflow path and a position that opens the outflow path.
A nozzle member that is fitted on one end of the housing and is slidably provided in the axial direction, and has a discharge path for discharging the liquid flowing out from the outflow path to the outside of the liquid coating module.
Liquid coating module with. A nozzle moving mechanism for moving the nozzle member in the axial direction is provided.
A claim that the nozzle moving mechanism is configured to move the nozzle member to the one side in the axial direction when the movable body moves from a position where the outflow path is opened to a position where the outflow path is closed. The liquid coating module according to 1. The movable body extends along the axial direction of the housing so as to be movable in the axial direction, and at a position moved to the one side in the axial direction, the movable body has a shaft shape that closes the opening on the flow path side of the outflow path. Believed to be
The liquid coating module
An urging member that urges the movable body toward the one side in the axial direction,
A movable body retracting mechanism that retracts the movable body to the other side in the axial direction against the urging force of the urging member, and
The liquid coating module according to claim 1 or 2. The nozzle member is formed so that the inner surface is in contact with the one-sided end surface of the housing, and the discharge path is in a state where the inner surface of the nozzle member and the one-sided end surface of the housing are in contact with each other. The liquid coating module according to claim 3, which is configured to communicate with the outflow path. The nozzle member is removable from the housing.
The liquid coating module according to any one of claims 1 to 4, wherein the flow path area of the outflow path is larger than the flow path area of the discharge path. The nozzle member has a contact portion that the nozzle member comes into contact with when moving to one side, and a contact portion holder that holds the contact portion in a changeable position in the axial direction. The liquid coating module according to any one of claims 1 to 5, further comprising a stopper mechanism for restricting the movement of the above to one side.

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