JP5150063B2 - Suction type injector - Google Patents

Description

  The present invention relates to a suction type injector.

JP-A-10-305243

Conventionally, in an aerosol injector, an object to be injected and a compressed gas for injection are generally accommodated in the same aerosol container (injection cylinder). Recently, only the compressed gas is stored in the injection cylinder, and the injection target (paint in Patent Document 1) is stored in a separate container, and the negative pressure generated by the injection of the compressed gas is used. There can be seen what sucks up and injects the injection target from the container (suction type injector).
As the above-mentioned gas for injection, it is conceivable to use a liquefied gas depending on the use other than the compressed gas.
The liquefied gas has two phases of a gas part and a liquid part in the cylinder, and the gas part is jetted from the cylinder at the time of use.

However, as a first problem, in the liquefied gas, vaporization of the liquefied portion is not in time for the vaporized gas injection, and the momentum of the injection tends to be attenuated immediately.
Further, as a second problem, there is a case where it is desired to use the injector in an inverted state in addition to using the injector in an upright state. In such a case, the liquefied gas always injects the vaporized portion located above the liquid portion regardless of the upper and lower sides of the cylinder, and the liquid ejected object in the container regardless of the upper and lower sides of the container. It is necessary to suck the liquid that is always below the air. There is no suction injector using a liquefied gas that can sufficiently cope with the use of both the upright state and the inverted state with a simple configuration.

  The first invention of the present application provides means for promoting the vaporization of the liquefied gas in the cylinder in the suction type injector utilizing the liquefied gas, and aims to solve the first problem. In addition, the second and third inventions of the present application provide means capable of performing smooth injection regardless of whether the injector is upright or inverted, thereby solving the second problem.

Therefore, the first invention of the present application includes an injection mechanism unit 3, an injection cylinder 2 connected to the injection mechanism unit, and an object storage chamber 4 connected to the injection mechanism unit 3 separately from the injection cylinder 2. The injection mechanism unit 3 employs the following configuration for a suction-type injector that sucks and injects the injection target in the injection target storage chamber 4 by discharging the gas in the injection cylinder 2. I will provide a.
That is, the injection cylinder 2 includes a gas storage chamber for storing liquefied gas, a port for opening the injection cylinder 2, and an opening / closing means 22 for the port. The gas storage chamber of the injection cylinder 2 is porous. A member 6 is provided. The gas storage chamber includes a tube having a base end connected to the opening / closing means 22 and the other end being an open end . Porous member above Symbol 6, at the gas storage chamber of the injection cylinder 2, in which at least a portion thereof is immersed in the portion of the liquid of the liquefied gas.

Further, in the upright state of the injector, the injection mechanism section 3 is located above the injection cylinder 2 and the injection object storage chamber 4. The above-mentioned injection target is a liquid. The injection cylinder 2 and the object storage chamber 4 have opening / closing means 22 and 42 for their mouths, first and second flow paths 23, 43, 24, and 44 disposed in the internal space, and valve means, respectively. 25, 45. Each of the first and second flow paths 23, 43, 24, and 44 has one end connected to the injection cylinder 2 or the opening of the injection object storage chamber 4, and the other end being an open end. In the upright state of the injector, the open ends of the first flow paths 23 and 43 are positioned below the liquid level, and the open ends of the second flow paths 24 and 44 are positioned above the liquid level. To do. In the inverted state of the injector, the open ends of the first flow paths 23 and 43 are located above the liquid level, and the open ends of the second flow paths 24 and 44 are located below the liquid level. . The valve means of the injection cylinder communicates vaporized gas above the liquid level through the second flow path 24 to the injection mechanism section 3 during the injection in the upright state, and the second flow path during the injection in the inverted state. Then, the liquid gas is disconnected from the injection mechanism unit 3 and the vaporized gas above the liquid level is communicated to the injection mechanism unit 3 through the first flow path 23. The valve means of the ejected object storage chamber 4 allows liquid to communicate with the ejection mechanism unit 3 through the first flow path 43 and air from the second flow path 44 to the ejection mechanism unit 3 during ejection in an upright state. The communication is cut off, and the liquid in the ejected object storage chamber 4 is communicated to the ejection mechanism unit 3 through the second flow path 44 during ejection in the inverted state. The first flow path 23 of the injection cylinder 2 is constituted by the tube, and the porous member is provided on the surface of the tube.

A second invention of the present application is the first invention of the present application, and provides a suction type injector having the following configuration.
That is, the injection cylinder 2 includes the opening / closing means 22, the first flow path 23, a flow path connection portion, and a liquid reservoir. The opening / closing means 22 includes a stem, a receiving portion that closes the mouth of the injection cylinder and receives the proximal end side of the stem, and a communication port that connects the receiving portion and the gas storage chamber. The stem is connected to the injection mechanism unit 3, and the communication port is closed and operated to open the communication port to connect the gas storage chamber in the injection cylinder 2 and the injection mechanism unit. To do. The first flow path 23 is disposed in the gas storage chamber of the injection cylinder 2 and has a base end connected to the opening / closing means 22 via the flow path connecting portion. When the injector is inverted, the liquid gas is liquefied. The vaporized gas located above the surface is guided toward the communication port. The flow path connection portion communicates the communication port and the first flow path 23, and the flow path connection portion has a base end of the first flow path 23 in an inverted state of the injector. The liquid reservoir is provided directly below and facing the opening on the proximal end side of the first flow path 23. When the injector is inverted, the liquid gas in the first flow path 23 can be dropped into the liquid reservoir, and the liquid gas is prevented from entering the communication port.

In the first and second inventions of the present application, by providing a porous member having a large surface area as compared with a material having a smooth surface, the liquid phase portion of the liquefied gas liquid portion has a large interface, Vaporization was made possible quickly. The interface here refers to a conversion surface (vaporization surface) from a liquid phase to a gas phase, and does not indicate only the above-described liquid surface. In other words, vaporization has been carried out using only the liquid surface as the conversion surface, but by providing a porous member, the bubbles entrained in the pores of the porous member promote the conversion from the liquid phase to the gas phase. And the conversion surface was enlarged inside the liquid portion.

This is because the present inventor uses the same phenomenon by paying attention to “boiling” which evaporates from the inside of the liquid as opposed to “evaporation” which evaporates only from the liquid surface during heating of the liquid such as water.
That is, the arrangement of the porous member described above is to obtain the same effect as that of adding boiling stones to prevent bumping. This bumping is a phenomenon in which, when a liquid is put in a smooth container and heated, boiling does not occur even when the temperature reaches the original boiling point, and suddenly vigorously occurs when the temperature becomes slightly higher than the boiling point. Evaporation (vaporization) is about to occur inside the liquid that has reached its boiling point, but even if very small vapor particles (bubbles) are formed, this phenomenon occurs because it collapses immediately. . The cause of the collapse is that the pressure of the liquid outside the bubbles is slightly higher than the pressure of the bubbles, and the bubbles are crushed. In order not to be crushed, the bubbles must be large to some extent. For this reason, a boiling stone having many holes in the surface is used. Air is contained in the hole of the boiling stone, which is a porous material, and as the temperature rises, the air in the hole expands to form air bubbles. When the boiling point is reached, the liquid evaporates over the bubbles of the air, and the generated bubbles come out as relatively large bubbles without being crushed.
The inventor of the present application has created the present invention based on the unusual idea of reproducing such a phenomenon of heating water or ethanol in a liquefied gas cylinder of an injector at room temperature.

In particular, in each invention of the present application, by adopting the above-described configuration, smooth injection can be performed even when the injector is used upside down as well as upright.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 8 show an embodiment of the present invention.
FIG. 1 is an overall sectional view (in an upright state) of a suction type injector according to an embodiment of the present invention. FIG. 2 is a sectional view of the injection cylinder of the suction type injector in an upright state. FIG. 3 is a sectional view of the injection cylinder of the suction type injector in an inverted state. 4 to 6 are enlarged cross-sectional views of a main part (in an upright state) of an injection object storage chamber of the suction type injector. FIG. 7 is an enlarged cross-sectional view of a further essential part (in an upright state) of the injection object storage chamber of the suction type injector. FIG. 8 is an enlarged cross-sectional view of a main part (in an inverted state) of an injection object storage chamber of the suction type injector. In FIG. 1, hatching is omitted for the sake of simplicity.
In each figure, for convenience of explanation, U indicates the upper side and S indicates the lower side. Moreover, in FIG. 1, F shows the front and B shows back.

As shown in FIG. 1, the suction type injector includes a casing 1 and an injection cylinder 2 attached to the casing 1.
The casing 1 includes an injection mechanism unit 3, an injection object storage chamber 4 that stores an injection object, and a cylinder storage unit 5 that stores the injection cylinder 2. The injection cylinder 2 and the injection object storage chamber 4 are respectively connected to the injection mechanism unit 3, and the injection mechanism unit 3 injects the gas from the injection cylinder 2 to inject the injection object storage chamber 4. Suction and inject things.

The ejected object storage chamber 4 is a space that is liquid-tightly covered with the casing 1 as an internal space of the casing 1. That is, the casing 1 is a plastic container having a side portion 12 and a bottom portion 13, and opens upward. The lid body 11 is attached to cover the opening portion. A space that is covered and liquid-tightly sealed by the lid body 11, the side portion 12, and the bottom portion 13 is the ejected object storage chamber 4. In this embodiment, the lid 11 is fixed to the casing 1 by an annular member 14 that is screwed onto the outer periphery of the upper end of the side portion 12 of the casing 1. The cylinder accommodating portion 5 is provided at the bottom of the lid 11, that is, at a portion facing the injection object accommodating chamber 4. The cylinder housing portion 5 is a liquid-tight container that is detachably attached to the lid body 11, and accommodates the above-described injection cylinder 2 in a replaceable manner. The injection cylinder 2 is stored in a state defined as the object storage chamber 4.
The injection mechanism section 3 is provided on the upper surface of the lid body 11, i.e., at a site where the outside of the casing 1 is desired. That is, in the upright state of the injector (casing 1), the injection mechanism portion 3 is located above the injection cylinder 2 and the object storage chamber 4.
The injection cylinder 2 contains a liquefied gas and includes a porous member. The porous member is a member in which at least a part of the porous member is immersed in the liquid part of the liquefied gas in the gas storage chamber of the injection cylinder.
Hereinafter, the configuration of each unit will be described in more detail.

First, the injection cylinder 2 will be specifically described.
As shown in FIG. 2, the inside of the injection cylinder 2 is a gas storage chamber 20 that stores the liquefied gas for injection. As the liquefied gas to be accommodated, for example, DME, HFC-152a, LPG, or fluorinated hydrocarbon can be employed. The liquefied gas may have a general pressure as an aerosol product or a higher pressure. Any type or pressure may be used as long as it can suck and inject an injection target in the injection target storage chamber described later.
The liquefied gas is divided into a vaporized portion (gas phase portion g1) and a liquid portion (liquid phase portion g2) in the gas storage chamber 20 of the injection cylinder 2. g0 indicates the interface between the vaporized portion and the liquid portion.
As shown in FIG. 2, the injection cylinder 2 includes a port 21 that opens upward of the cylinder, an opening / closing means 22 for the port 21, a first flow path 23 disposed in the gas storage chamber 20, and a gas. A second flow path 24 disposed in the storage chamber 20, valve means 25 for opening and closing the second flow path 24, a flow path connection portion 26, a liquid reservoir 27, and the porous member 6 are provided.
Hereinafter, the opening / closing means 22 is the cylinder opening / closing means 22, the first flow path 23 is the first gas flow path 23, the second flow path 24 is the second gas flow path 24, and the valve means 25 is the liquid valve means 25. Call it.

2 and 3, at least a part of the porous member 6 is immersed in the liquid portion g2 of the liquefied gas in both the upright state and the inverted state of the cylinder (see FIG. 2). The whole may be immersed as shown).
The porous member 6 is made of foamed urethane such as sponge, foamed polyethylene, porous ceramic, sintered member typified by porous plastic (porous polypropylene, porous polyethylene), non-woven fabric, boiling stone such as zeolite. Can be adopted.
About the hole with which the said porous member 6 is provided, although it changes with kinds of gas, generally what has a diameter of 10-500 micrometers is preferable.
However, depending on conditions such as temperature and pressure, it can be carried out even outside the range of such numerical values.

In this embodiment, the porous member 6 is attached to the surface of the first flow path 23. That is, the porous chamber member 6 is provided from the lower end to the upper end of the first flow path 23 so as to include the first flow path 23 with the first flow path 23 as the center. For example, when a material having a regularity such as ceramic or urethane is adopted for the porous member 6, a through-hole penetrating vertically is provided in the center of the porous member 6, and the first flow path 23 is fitted into the through-hole. Can be attached to fit. In addition, the porous member 6 can be provided by being provided on the inner peripheral surface of the gas storage chamber 20. In this case, even if the cylinder is turned upside down (inverted), the porous member 6 is always immersed in the liquid portion of the liquefied gas over the entire area in the vertical direction of the gas storage chamber 20, It is preferable to dispose the porous member 6 in advance. For fixing the porous member 6, an adhesive is used, and the attachment position of the gas storage chamber 20 is formed in a shape that can receive the porous member 6, or a known jig such as a screw or a screw is used. Can be attached. In addition to the above, a jig that can be tied, such as a string or a band, can be used as the jig.
Further, the porous member 6 may be stored in the gas storage chamber 20 together with the liquefied gas without being fixed at a specific position in the gas storage chamber 20 as described above (in this case, the porous member 6 is porous). The member 6 can move up and down together with the liquefied gas when the cylinder is upright or inverted.

  The cylinder opening / closing means 22 includes a stem 28, a receiving portion 29 that closes the mouth of the injection cylinder 2 and receives the proximal end side of the stem, an urging means 29 a provided in the receiving portion 29, and the receiving portion 29 There is provided a communication port 21 a that communicates with the gas storage chamber 20. The stem 28 is connected to the injection mechanism 3 and closes and operates the cylinder opening / closing means 22 to open the opening / closing means 22. Thus, by opening the opening / closing means 22 with the stem 28, the gas storage chamber 20 in the injection cylinder 2 and the injection mechanism unit 3 can be communicated with each other through the communication port 21a. Each of the first gas flow path 23 and the second gas flow path 24 has a base end 23a, 24a connected to the cylinder opening / closing means 22 via the flow path connecting portion 26, and the other end being an open end. 23b and 24b.

The biasing means 29a always biases the stem 28 in a direction to close the cylinder opening / closing means 22. That is, unless the force for operating the stem 28 is applied to the stem 28, the stem 28 is disposed at a position where the cylinder opening / closing means 22 is closed by the urging means 29a. When the stem 28 is actuated by applying a force against the urging force of the urging means 29a and the gas is injected and then the applied force is released, the urging means 29a returns the stem 28 to the original position. The cylinder opening / closing means 22 can be closed. A spring can be adopted as the biasing means 29a.
In this embodiment, the first gas flow path 23 is a tube. The liquid valve means 25 is provided at the open end 24 b of the second gas flow path 24. The liquid valve means 25 accommodates the valve body 25a and includes a gas introduction port 25b.
The base ends 23 a and 24 a of the first gas channel 23 and the second gas channel 24 are connected to the cylinder opening / closing means 22 through the channel connection part 26.

  As shown in FIG. 2, in the upright state of the injector (injection cylinder 2), the open end 23b of the first gas passage 23 is located below the liquid level g0 of the liquefied gas, and the second gas flow The open end 24b of the path 24 is located above the liquid level g0 of the liquefied gas. In this state, the valve body 25 a of the liquid valve means 25 opens the open end 24 b of the second gas flow path 24. In this state, as shown in FIG. 2, when the stem 28 is operated (in this embodiment, the stem 28 is operated downward) and the communication port 21a of the cylinder opening / closing means 22 is opened, the liquefied gas is vaporized. The portion g1 passes through the gas inlet 25b of the liquid valve means 25 and is guided from the open end 24b into the second gas flow path 24, and further from the base end 24a of the second gas flow path 24 to the flow path connection portion 26. Then, it is guided into the communication port 21a. The vaporized portion g1 of the liquefied gas passes through the hollow stem 28 and is discharged to the outside of the injection cylinder 2 (injection mechanism unit 3).

  As shown in FIG. 3, in the inverted state of the injector (injection cylinder 2), the open end 23b of the first gas flow path 23 is located above the liquid level g0, and the open end of the second flow path described above. 24b is located below the liquid level g0. In this state, the valve element 25a of the liquid valve means 25 is displaced by gravity, closes the open end 24b of the second gas passage 24, and prevents the liquid portion g2 of the liquefied gas from entering the second gas passage 24. . Then, as shown in FIG. 3, when the stem 28 is operated and the connection port 21 a is opened in the same manner as described above, the vaporized portion g1 of the liquefied gas is in the first gas flow path 23 positioned above the liquid level g0. From the open end 23b, the gas enters the first gas flow path 23, and enters the communication port 21a from the base end 23a of the first gas flow path 23 through the flow path connection portion 26. Then, the vaporized portion g1 of the liquefied gas passes through the stem 28 in the same manner as described above and is discharged to the outside of the injection cylinder 2 (injection mechanism unit 3).

The liquid reservoir 27 is provided inside the flow path connection portion 26 so as to face the opening on the proximal end side of the first gas flow path 23. That is, as shown in FIG. 3, in the inverted state of the injector, the liquid reservoir 27 is provided immediately below the base end 23 a of the first gas flow path 23, and is located at a position outside the base end 23 a. The communication port 21a is arranged.
As described above, when the injection cylinder 20 is inverted from the upright state, the liquid portion g2 of the liquefied gas accumulated in the first gas flow path 23 can be dropped into the liquid reservoir 27 and vaporized. It is possible to prevent the portion g0 from passing through the first gas flow path 23.

Next, the above-described ejected object storage chamber 4 will be described.
The injection object stored in the injection object storage chamber 4 can be freely selected and implemented on the condition that it can be sucked by the injection of the injection gas, such as a fragrance, a deodorant, and a cleaning agent. It is a liquid fluid such as liquid daily necessities, cosmetics, pharmaceuticals, paints, inks, alcohol, and water. That is, as shown in FIG. 1, the liquid storage chamber 4 stores such a liquid as the liquid injection object W1. By removing the lid 11, the ejected object W <b> 1 can be accommodated in the ejected object storage chamber 4.
1, FIG. 4 to FIG. 6 and FIG. 8, W0 indicates the liquid level of the injection target W1. In the ejected object storage chamber 4, the air W2 is above the liquid level W0.
4 shows a state of the stem 48 described below before operation, FIG. 5 shows a state during the operation of the stem 48, and FIG. 6 shows a state where the test 48 is completely operated. Yes.

As shown in FIGS. 1 and 4, the injection object storage chamber 4 includes a port 41 that opens upward from the injection object storage chamber 4, an opening / closing means 42 for the port 41, and the injection object storage chamber 4. A first flow path 43 disposed in the interior, a second flow path 44 disposed in the same to-be-injected object storage chamber 4, valve means 45 for opening and closing the second flow path 44, and a flow path connection portion 46. Is provided.
Hereinafter, the opening / closing means 42 is the liquid opening / closing means 42, the first flow path 43 is the first liquid flow path 43, the second flow path 44 is the second liquid flow path 44, and the valve means 45 is the air valve means 45. Call it.
In this embodiment, the opening 41 is provided in the lid 11 that defines the upper side of the ejected object storage chamber 4 from the outside. In addition, the liquid opening / closing means 42, the first liquid flow path 43, the second liquid flow path 44, and the air valve means 45 are provided in a portion of the lid body 11 where the inside of the ejected object storage chamber 4 is desired. .

  As shown in FIG. 4, the liquid opening / closing means 42 includes a stem 48, a receiving portion 49 that closes the mouth 41 of the injection object storage chamber 4 and receives the proximal end side of the stem, an urging means 49 b, A communication port 41 a is provided for connecting the receiving portion 49 and the ejected object storage chamber 4. The stem 48 is connected to the injection mechanism unit 3 and closes and operates the communication port 41a to open the communication port 41a, and the ejected object storage chamber 4 and the injection mechanism unit 3 To contact. As shown in FIGS. 1 and 4, the first liquid flow path 43 and the second liquid flow path 44 have base ends 43 a and 44 a that are connected to the liquid opening / closing means 42 via the flow path connection portion 46. The other ends are open ends 43b and 44b.

The biasing means 49b always biases the stem 48 in the direction to close the liquid opening / closing means 42. That is, unless a force for operating the stem 48 is applied to the stem 48, the stem 48 is disposed at a position where the liquid opening / closing means 42 is closed by the biasing means 49b. When the stem 48 is operated by applying a force against the urging force of the urging means 49b and the applied force is released after the liquid is discharged, the stem 48 is returned to the original position by the urging means 49b. The liquid opening / closing means 42 can be closed. A spring can be adopted as the biasing means 49b.
In this embodiment, the first liquid channel 43 is a tube. The air valve means 45 is provided at the open end 44 b of the second liquid channel 44. The air valve means 45 accommodates a valve body 45a and includes a liquid inlet 45b.
The base ends 43 a and 44 a of the first liquid channel 43 and the second liquid channel 44 are connected to the liquid opening / closing means 42 through the channel connection part 46.

  As shown in FIGS. 1 and 4, in the upright state of the injector (casing 1), the open end 43b of the first liquid channel 43 is located below the liquid level W0 of the injection target W1, and the above-mentioned The open end 44b of the second liquid channel 44 is located above the liquid level W0 of the injection target W1. In this state, the valve body 45 a of the gas-liquid valve means 45 closes the open end 44 b of the second liquid channel 44 and prevents the air W <b> 2 from entering the channel connecting part 46. In this state, as shown in FIGS. 5 and 6, when the stem 48 is operated (in this embodiment, the stem 48 is operated downward) to open the communication port 41 a of the liquid opening / closing means 42, the injection cylinder Due to the injection of the gas 2, the object W <b> 1 is sucked into the first liquid channel 43 from the open end 43 b of the first liquid channel 43 due to the negative pressure generated outside the object storage chamber 4. The first liquid channel 43 enters the communication port 41a from the base end 43a through the channel connection portion 46, and is discharged to the outside of the casing 1 through the hollow stem 48 and the injection mechanism unit 3. Is done.

  As shown in FIG. 8, in the inverted state of the injector (casing 1), the open end 43b of the first liquid channel 43 is positioned above the liquid level W0, and the second liquid channel 44 is opened. The end 44b is located below the liquid level W0. In this state, the valve body 45 a of the air valve means 45 is displaced by gravity and opens the open end 44 b of the second liquid flow path 44. In this state, as shown in FIG. 8, when the stem 48 is operated and the communication port 41a is opened in the same manner as described above, the injection target W1 that has received the negative pressure of the injection is positioned below the liquid level W0. The second liquid flow path 44 is sucked into the second liquid flow path 44 from the open end 44b, and from the base end 44a of the second liquid flow path 44 to the communication port 41a through the flow path connecting portion 46. enter. And the to-be-injected object W1 is discharged | emitted to the exterior of the casing 1 through the hollow stem 48 inside and the injection mechanism part 3 similarly to the above.

In the above, in order to smoothly discharge the injection target W1 by the negative pressure generated outside the injection target storage chamber 4, the discharge target W1 from the outside of the casing 1 with the discharge of the liquid injection target W1. It is necessary to introduce air into the storage chamber 4.
Next, a more specific configuration for discharging the injection target W1 will be described with reference to FIGS.

As shown in FIG. 4, the stem 48 includes a cylindrical stem main body 48a, an extended portion 48b of the stem main body 48a, and an annular portion 48c loosely fitted on the outer periphery of the extended portion 48b. The annular portion 48c can slide with respect to the axial direction of the extending portion 48b. The extending portion 48b is a cylindrical body, is integral with the stem body 48a, and the inside communicates with the inside of the stem body 48a. The extending portion 48b is exposed from the inside of the proximal end of the cylindrical stem body 48a to the outside of the proximal end of the stem body 48a. The distal end (lower end in the upright state) of the extended portion 48b is closed, and holes 48g and 48g that connect the inside and the outside of the extended portion 48b are formed on the side surface.
On the other hand, a gap a <b> 1 is formed between the outer periphery of the stem main body 48 a and the inner peripheral surface of the mouth 41 of the ejected object storage chamber 4 so as to prevent air from passing therethrough.
Further, the periphery of the mouth 41 is provided with a raised portion 11a raised toward the inside of the ejected object storage chamber 4, and the liquid opening / closing means 42 is connected to the raised portion 11a so as to be integrated with the raised portion 11a. . However, an intermittent part a <b> 2 that is not partially connected is formed between the raised part 11 a and the liquid opening / closing means 42.

  The outer periphery of the lower end portion of the annular portion 48c contacts the inner peripheral surface of the receiving portion 49. The annular portion 48c has a shoulder portion 48d as a first contact portion on the outer peripheral surface, and an inner shoulder portion 48e as a second contact portion on the inner peripheral surface. On the other hand, the extended portion 48b includes an outer shoulder portion 48f that comes into contact with the inner shoulder portion 48e of the annular portion 48c as a second contacted portion on the tip side from the holes 48g and 48g. The urging means 49b constantly urges the extending portion 48b and presses the extending portion 48b against the annular portion 48c as long as no force is applied to the stem 48. The state where the shoulder 48f is in contact is maintained. In this state where the extended portion 48b is pressed, the annular portion 48c is disposed at a position where the holes 48g and 48g are closed. Therefore, in the state where the stem is not actuated as shown in FIG. 4, the inside of the stem 48 (stem body 48a) and the communication port 41a of the receiving portion 49 are blocked by the annular portion 48c. The mouth 41 of the storage quality 4 is closed (in this state, the upper end of the annular portion 48c abuts on the stem body 48a and does not pass through the blocking position).

At this time, as shown in FIG. 4, the shoulder portion 48d of the annular portion 48c, which is the first contact portion, is in contact with the tip of the raised portion 11a, which is the first contact portion, and the intermittent portion The contact between a2 and the gap a1 is blocked (sealed).
As shown in FIG. 4 (in an upright state), the inner peripheral surface of the receiving portion 49 is below the closed annular portion 48c with respect to the lower end portion of the annular portion 48c serving as the third contact portion. A step 49a serving as a third contacted portion is provided so as to face each other. 4, the lower end (third contact portion) of the annular portion 48c is spaced upward from the step 49a (third contacted portion).

  As shown in FIG. 5, when the stem 48 is operated (actuated downward in this embodiment) and the extending portion 48b is moved downward, the inner shoulder portion 48e (second contact portion) of the annular portion 48c. Thus, the outer shoulder portion 48f (second contacted portion) of the extending portion 48b is moved downward, and the holes 48g and 48g are opened from the annular portion 48c. Thus, the injection target W1 can move from the communication port 41a into the stem 48.

When the stem 48 is further operated, as shown in FIGS. 6 and 7, it is pushed by the lower end of the stem main body 48a (the base end when there is no extending portion 48b), and the annular portion 48c also moves downward. (Finally, the lower end (third contact portion) of the annular portion 48c contacts the step 49a (third contacted portion) and stops moving downward). Thereby, the shoulder portion 48d (first contact portion) of the annular portion 48c is separated from the tip of the raised portion 11a (first contact portion), and the intermittent portion a2 and the gap a1 communicate with each other. Air can be introduced into the ejected object storage chamber 4 from the outside of the casing 1 (FIG. 7). And as shown in FIG. 6, discharge | emission of the above-mentioned to-be-injected object W1 can be performed.
As shown in FIG. 8, even when the apparatus is used upside down, the liquid can pass through the air introduction passage (intermittent part a2 and the gap a1) by the surface tension so that the liquid does not leak. It should be set to a width that does not.

  After use, after the ejected object W1 is discharged, the force applied to the stem 48 is released, and the urging means 49b urges the extending portion 48b from the state shown in FIG. ) Start recovery. Although not shown, during the return, the outer shoulder 48f (second contacted portion) of the extended portion 48b again comes into contact with the inner shoulder 48e (second contacting portion) of the annular portion 49c, thereby The part 48c is pushed back to the position before the operation (upward) by the extending part 48b. And each said part returns to the state of FIG.

Next, the injection mechanism unit 3 will be described.
As shown in FIG. 1, the injection mechanism unit 3 is provided on the lid 11 of the casing 1, and the injection cylinder 2 and the stems 28 and 48 of the injection object storage chamber 4 are connected to each other. Specifically, the injection mechanism unit 3 includes a support part 31 provided on the lid body 11 of the casing 1 and an operation main body 32 pivotally fixed to the support part 31. The operating body 32 is attached to the support portion 31 so as to be rotatable about a shaft 33. The operation main body 32 includes an injection unit 34, a cylinder connection unit 35, a storage chamber connection unit 36, and a finger hook unit 37. The cylinder connecting portion 35 is connected to the stem 28 of the injection cylinder 2. The storage chamber connection portion 36 is connected to the stem 48 of the injection target storage portion 4. The injection unit 34 includes a nozzle unit 34a for injecting gas, a negative pressure generation chamber 34b provided in the injection direction of the nozzle unit 34a (in front of the nozzle unit 34a), and an injection port 34c provided in the negative pressure generation chamber 34b. With. The cylinder connecting portion 35 communicates with the nozzle portion 34a. Further, the negative pressure generating chamber 34 b communicates with the storage chamber connecting portion 36.

  When the injector is used, the operation main body 32 can be rotated toward the lower injection cylinder 2 and the object storage chamber 4 around the shaft 33 by hooking and pulling a finger on the finger-holding portion 37. it can. By this rotation, the stem 28 of the injection cylinder 2 connected to the cylinder connection part 35 and the stem 48 of the injection object storage part 4 connected to the storage chamber connection part 36 can be operated simultaneously. By the operation of the stem 28 of the cylinder connection part 35, the vaporized gas is sent to the nozzle part 34a, and is injected from the nozzle part 34a to the outside through the negative pressure generating chamber 34b. By this gas injection, a negative pressure is generated in the negative pressure generating chamber 34b, and the negative object generates a negative pressure by the operation of the stem 48 in the object W1 that is opened in the object storage part 4 opened. The air is sucked into the chamber 34b and is ejected together with the gas from the ejection port 34c.

In the above-described embodiment, the casing 1 is configured such that the cylinder storage portion 5 is attached to the lid body 11 serving as the top portion, and the cylinder storage portion 5 is disposed in the injection object storage chamber 4. In addition, although not shown, the cylinder storage portion 5 is not disposed in the ejected object storage chamber 4, but the casing 1 itself is formed in a donut shape (of course, the inner ejected object storage chamber 4 is also a donut shape). It is also possible to implement the method by storing the injection cylinder 2 in the central hollow portion. The housing 1 can be changed to a shape other than the above.
When the surface of the injection cylinder 2 may be in direct contact with the injection object in the injection object storage chamber 4, unlike the above, the injection cylinder 2 is directly arranged in the injection object storage chamber 4. Even so, it can be implemented. For example, the injection cylinder 2 itself can be made of resin.
The above-described injection mechanism 3 is a trigger type, that is, the operation main body 32 is rotated about the shaft 33 by pulling the finger hanging portion 37 to operate both the stems 28 and 48. In addition, the operation main body 32 does not rotate around the shaft 33, that is, does not pull the finger hanger 37 (without the finger hanger 37), but pushes it downward from above, so that both stems 28, It is also possible to adopt a type in which 48 is operated downward.
The opening / closing means and the valve means of the injection cylinder 2 and the injection object storage chamber 4 are not limited to those of the above-described embodiment, and may be implemented even if other known forms are adopted.

According to the suction type injector according to the present invention, the spraying force is lowered without instantaneously vaporizing in the liquid phase portion, which has been a problem in the conventional liquefied gas injection, that is, apparently within a few seconds, 0.2 to 0.3 MPa
Although such a pressure drop occurred, the pressure drop was improved by the arrangement of the porous member 6 described above.
For example, when HFC-152a is employed as the liquefied gas, it is possible to secure a time of about 30 seconds for the drop (halved) of the injection pressure P from 0.5 MPa to 0.25 MPa.
Regarding this pressure drop, the test results of the injector according to the present invention are shown below.
1) to 4) indicate the time from the porous member / immediately after the injection until the change in the injection momentum occurs.
1) None / 2 to 3 seconds 2) Sponge / 15 to 20 seconds 3) Sintered member / 15 to 20 seconds 4) Zeolite / 10 to 15 seconds

As the sponge of 2), 0.15 g / 8 cm @ 3 (weight of 0.15 g for a cube having a side of 2 cm) was used. Further, as the sintered member of 3), a sintered material of polyethylene powder was adopted. However, even when a sintered member obtained by sintering polyethylene powder was used, the result was the same as that obtained by sintering the polyethylene powder. For the zeolite 4), silicon dioxide mineral was used.

  As described above, in any case 2) to 4) in which the porous member is employed, the improvement is required to take 10 seconds or more until a change in injection is observed. From this, it can be seen that a significant improvement has been made as compared to 1) in which the porous member in which the change in injection occurs in 2 to 3 seconds is not used.

  Further, in the cylinder of liquefied gas and the object storage section, it is necessary to discharge one from the vaporized gas and the other from the liquid. In the injector according to the present invention, such discharge can be performed at the same time in both the upright use and the inverted use, and the venturi, that is, the suction type injector, can be covered with a simple structure. It was made possible to reliably perform the injection of the projectile.

It is a whole sectional view of a suction type injector concerning an embodiment of the invention of this application. It is sectional drawing of the injection cylinder of the said injector at the time of the injection in an erect state. It is sectional drawing of the injection cylinder of the said injector at the time of the injection in an inverted state. It is a partial notch principal part sectional view of a to-be-injected article storage chamber at the time of non-operating in an upright state. It is a partial notch principal part sectional view of a to-be-injected article storage chamber in the middle of operation in an upright state. It is a partial notch principal part sectional view of a to-be-injected object storage chamber at the time of the completion | finish of operation | movement in an erect state. FIG. 7 is an enlarged cross-sectional view of a partly cutaway main portion of FIG. 6. It is a partial notch principal part sectional view of a to-be-injected object storage chamber at the time of the completion | finish of operation | movement in an inverted state.

DESCRIPTION OF SYMBOLS 1 Casing 2 Injection cylinder 3 Injection mechanism part 4 Injected object storage chamber 6 Porous member

Claims (2)

An injection mechanism unit, an injection cylinder connected to the injection mechanism unit, and an object storage chamber connected to the injection mechanism unit separately from the injection cylinder, the injection mechanism unit ejecting gas from the injection cylinder In the suction type injector that sucks and injects the injection target in the injection target storage chamber,
The injection cylinder includes a gas storage chamber that stores a liquefied gas, a port that opens the injection cylinder, and an opening / closing means for the port, and the gas storage chamber of the injection cylinder includes a porous member,
The gas storage chamber includes a tube having a base end connected to the opening / closing means and the other end being an open end ,
Porous member above SL, at the gas storage chamber of the injection cylinder, which at least a portion thereof is immersed in the portion of the liquid of the liquefied gas,
In the upright state of the injector, the injection mechanism portion is located above the injection cylinder and the object storage chamber,
The above-mentioned injection target is a liquid,
The injection cylinder and the object storage chamber each include opening / closing means for its mouth, first and second flow paths arranged in the internal space, and valve means,
Each of the first and second flow paths is connected at one end to the injection cylinder or the mouth of the object storage chamber, and the other end is an open end.
In the upright state of the injector, the open end of the first flow path is located below the liquid level, and the open end of the second flow path is located above the liquid level,
In the inverted state of the injector, the open end of the first flow path is located above the liquid level, and the open end of the second flow path is located below the liquid level,
The valve means of the injection cylinder communicates the vaporized gas above the liquid level through the second flow path to the injection mechanism part during the injection in the upright state, and the liquid from the second flow path during the injection in the inverted state. The gas is communicated to the injection mechanism, and the vaporized gas above the liquid level is communicated to the injection mechanism through the first flow path.
The valve means in the ejected object storage chamber causes liquid to communicate with the ejection mechanism through the first flow path and eject air from the second flow path to the ejection mechanism when ejecting in an upright state. When injecting in an inverted state, the liquid in the object storage chamber is communicated to the injection mechanism through the second flow path,
The suction type injector , wherein the first flow path of the injection cylinder is constituted by the tube, and the porous member is provided on a surface of the tube . The injection cylinder includes the opening / closing means, the first flow path, a flow path connecting portion, and a liquid reservoir.
The opening / closing means includes a stem, a receiving portion that closes the mouth of the injection cylinder and receives the proximal end side of the stem, and a communication port that connects the receiving portion and the gas storage chamber.
The stem is connected to the injection mechanism unit, and closes the communication port and operates to open the communication port to communicate the gas storage chamber in the injection cylinder with the injection mechanism unit. And
The first flow path is arranged in the gas storage chamber of the injection cylinder, the base end is connected to the opening / closing means via the flow path connecting portion, and is above the liquid level of the liquefied gas when the injector is inverted. The vaporized gas located at is directed to the above-mentioned connection port,
The flow path connecting portion communicates the communication port and the first flow path, and the flow path connecting portion has an inside of the flow path connecting portion directly below the base end of the first flow path in an inverted state. The liquid reservoir is provided so as to face the opening on the proximal end side of the first flow path,
When the injector is inverted, the liquid gas in the first flow path can be dropped into the liquid reservoir, and the liquid gas is prevented from entering the communication port. The suction type injector according to claim 1 .

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