JP6182469B2 - Discharge container - Google Patents

Description

  The present invention relates to a discharge container.

Conventionally, for example, as shown in Patent Document 1 below, a nozzle cylinder that extends forward, a discharge head that is mounted on a container body in which the contents are accommodated, and is mounted on the container body, 2. Description of the Related Art A discharge container is known that includes a cover body that surrounds a discharge head and is formed with a passage hole in which a nozzle cylinder protrudes and retracts as the discharge head moves back and forth.
According to this discharge container, since the nozzle cylinder can be accommodated inside the cover body in a standby state before the contents are discharged, the nozzle cylinder can be prevented from getting in the way, and the appearance of the discharge container is deteriorated in appearance. Can be prevented.

Utility Model Registration No. 2539181

  However, in the above-described conventional discharge container, when discharging the contents, the operation of moving the discharge head forward relative to the cover body to project the nozzle cylinder from the passage hole and the operation of pressing the discharge head are performed separately. Need to be done. In addition, after discharging the contents, an operation of moving the discharge head backward relative to the cover body is also required. Thus, when discharging the contents, it is necessary to perform a plurality of operations separately, and there is room for improvement in operability.

  The present invention has been made in view of such circumstances, and the purpose thereof is to keep the nozzle cylinder in the standby state before discharging the contents, maintain good design, and discharge. An object of the present invention is to provide a discharge container that has excellent operability at the time and can easily discharge contents.

In order to achieve the above object, the present invention provides the following means.
(1) A discharge container according to the present invention includes a container main body in which contents are stored, a nozzle cylinder extending in the front-rear direction and having discharge holes for discharging the contents at a front end thereof. A discharge device including a discharge head mounted on the main body so as to be able to be pushed down in an upwardly biased state; a container for slidably moving the container main body and the discharge device along the front-rear direction; and And an outer container having an operation head mounted on the container so as to be movable downward with respect to the discharge head. The operation head projects downward, and An operation protrusion for slidingly moving the container main body and the discharger forward with respect to the outer container by slidingly contacting an engagement protrusion provided on the container main body or the discharger as it moves downward. And lowering of the operation head A pressing portion that presses the discharge head with movement, and the outer container passes through the nozzle cylinder as the container main body and the discharger slide forward with respect to the outer container. A nozzle window that protrudes outward of the outer container, and a first attachment that slides the container body and the discharge device backward relative to the outer container to return the nozzle cylinder to its original position. A biasing member is provided.

According to this discharge container, when the operation head is moved downward, the operation protrusion slides on the engagement protrusion and slides the container body and the discharge device forward with respect to the outer container. The mounted discharge head can be slid forward. Thereby, the nozzle cylinder accommodated inside the outer container can be protruded outward of the outer container through the nozzle window.
On the other hand, as the operation head moves downward, the pressing unit presses the discharge head, so that the contents can be discharged from the discharge hole of the nozzle cylinder. At this time, as described above, since the nozzle cylinder has already protruded outward from the outer container, the contents can be discharged without being interfered by the outer container.

  When the lowering of the operating head is released after the contents are discharged, the upwardly biased discharging head moves upward to return to the original position, so that the operating head is pushed up by the discharging head and returns to the original position. . At the same time, the first urging member urges the container body and the discharger toward the rear with respect to the outer container and slides them, so that the nozzle cylinder can be returned to the original position. Thereby, a nozzle cylinder can be again accommodated in an outer container.

As described above, since the forward movement operation of the discharge head and the discharge operation of the contents can be simultaneously performed in a series of flows by one operation of moving the operation head downward, the contents can be easily discharged. It is possible to improve the operability at the time of discharge. Moreover, since the first urging member moves the container body and the discharge device backward, the nozzle cylinder is naturally returned to the original position, so that the operability can also be improved.
In addition, since the nozzle cylinder can be accommodated in the outer container during the standby state before discharging the contents, the nozzle cylinder can be prevented from becoming an obstacle, and the appearance of the appearance can be prevented from deteriorating. Can be maintained.
Further, for example, unlike the case where the discharge head is configured in a complicated manner and only the discharge head is slid, the container main body and the discharge device have a simple structure in which the engagement protrusion is protruded from the container main body or the discharge device. The entire structure is slid, so that the configuration can be easily simplified and the cost can be easily reduced.

(2) The outer container may be provided with a second urging member that urges the operation head upward with respect to the container.

  In this case, the second urging member urges the operation head upward to release the operation head when the downward movement of the operation head is released after the contents are discharged. The operation head can be smoothly returned to the original position. Further, since the pushing load on the operation head is reduced, the ejection head can be returned to the original position smoothly. Therefore, the operability can be further improved.

(3) The container may be provided with a guide member that guides the container body so as to be slidable along the front-rear direction.

  In this case, since the guide member guides the sliding movement of the container body, the container body and the discharger can be slid more reliably along the front-rear direction without rotating around the container axis. Accordingly, the nozzle cylinder can be accurately projected and retracted through the nozzle window.

(4) The pressing unit is disposed above the discharge head with a space therebetween, and after the operation projecting piece slides the container body and the discharger, the pressing unit starts to press the discharge head. May be.

  In this case, when discharging the contents, the contents can be discharged after the discharge head is moved forward and the nozzle cylinder protrudes outward of the outer container. Therefore, since the contents are not discharged while moving the nozzle cylinder forward, it is easy to discharge the contents to the target position.

  According to the present invention, the nozzle cylinder does not get in the way in the standby state before discharging the contents, can maintain a good design, and is excellent in operability at the time of discharging, and can easily discharge the contents. it can.

It is a longitudinal cross-sectional view which shows embodiment of the discharge container which concerns on this invention. It is sectional drawing along the arrow AA shown in FIG. It is sectional drawing along the arrow BB line shown in FIG. It is sectional drawing which shows the state which moved the operating head down from the state shown in FIG. 1, and slid the nozzle cylinder ahead of the outer container. It is sectional drawing along the arrow CC line shown in FIG. FIG. 5 is a cross-sectional view illustrating a state where the operation head is further moved downward from the state illustrated in FIG. 4 and the contents are discharged from the discharge hole of the nozzle cylinder.

Hereinafter, an embodiment of a discharge container according to the present invention will be described with reference to the drawings.
(Configuration of discharge container)
As shown in FIG. 1, a discharge container 1 according to this embodiment includes a container main body 2 that stores contents, a discharger 3 that discharges contents, and an outer container 4 that stores the container main body 2 and the discharger 3. And.
In the present embodiment, a pump-type discharger 3 that discharges contents using a pump will be described as an example. Further, the content is not particularly limited, and may be, for example, liquid, gel or cream.

The container body 2 and the discharger 3 are arranged with their respective central axes positioned on a common axis. Hereinafter, this common axis is referred to as a container axis O, the discharger 3 side along the container axis O is referred to as the upper side, and the opposite side is referred to as the lower side. Further, in a plan view viewed from the container axis O direction, a direction orthogonal to the container axis O is referred to as a radial direction, and a direction around the container axis O is referred to as a circumferential direction.
Furthermore, in the radial direction, a direction in which a discharge hole 21a of the nozzle cylinder 21 described later faces is referred to as the front, the opposite direction is referred to as the rear, and the direction connecting these is referred to as the front-rear direction L1. Moreover, the direction orthogonal to the front-back direction L1 among radial directions is called the left-right direction L2.

(Container body)
The container body 2 is formed in a bottomed cylindrical shape having a mouth portion (not shown) formed in the upper portion, and a main container 10 in which contents are accommodated, and a bottomed cylindrical support container 11 in which the main container 10 is accommodated. And.

  As shown in FIGS. 1 and 2, the support container 11 includes a trunk portion 11 a and a bottom portion 11 b that surround the main container 10 from the radially outer side. The trunk portion 11a is formed at a height that surrounds at least the lower half of the main container 10. Thereby, the main container 10 is stably supported in the support container 11.

An engagement rib (engagement protrusion) 12 projects from the rear portion of the trunk portion 11a of the support container 11 toward the rear. The engagement rib 12 is formed in a vertically long shape along the vertical direction on the body portion 11 a of the support container 11.
Specifically, the engagement rib 12 is formed from the lower end portion of the trunk portion 11a to a portion located slightly below the upper end portion of the trunk portion 11a. The upper end portion of the engagement rib 12 is an inclined surface 12a that gradually inclines from the upper side to the lower side as it goes rearward.
In the illustrated example, a plurality (three) of the engaging ribs 12 are formed so as to be arranged in parallel in the left-right direction L2. However, the number of the engagement ribs 12 is not limited to this case. For example, only one wide engagement rib 12 may be provided in the left-right direction L2.

  Further, two auxiliary ribs 13 are formed in parallel to the engaging ribs 12 at the rear portion of the trunk portion 11a of the support container 11 so as to sandwich the plurality of engaging ribs 12 from the left-right direction L2. These auxiliary ribs 13 protrude rearward with a projection amount similar to that of the engaging rib 12 and are formed in a vertically long shape from the lower end portion of the trunk portion 11a to the upper end portion of the trunk portion 11a.

An upper flange 14 and a lower flange 15 projecting outward in the radial direction are formed at the upper end and the lower end of the body 11a of the support container 11. The upper flange 14 and the lower flange 15 are formed in a portion excluding the front portion of the body portion 11a and are connected to the auxiliary rib 13 from the circumferential direction.
2 shows the lower flange 15, the upper flange 14 shown in FIG. 1 has the same shape.

(Discharger)
As shown in FIG. 1, the discharger 3 has a stem (not shown) that stands upright so as to be able to be pushed in an upward biased state, and has a pump part (not shown) that feeds contents by pushing the stem and a discharge hole 21a. An ejection head 20 having a nozzle cylinder 21.

  The pump section includes a cylinder cylinder 23 that is integrally assembled with a mounting cap 22 that is mounted on the mouth of the main container 10, and a piston cylinder (not shown) that is inserted into the cylinder cylinder 23 so as to be slidable up and down. The stem is attached to the upper part of the piston cylinder in a communicating state. Note that the piston cylinder and the stem are biased upward by a coil spring (not shown).

The discharge head 20 is formed in a top tube shape and attached to the upper end portion of the stem. Accordingly, the discharge head 20 is mounted on the main container 10 so as to be able to be pressed down in the upward biased state via the stem. The nozzle cylinder 21 protrudes from a part of the side surface of the discharge head 20 toward the radially outer side of the container axis O. As described above, the axial direction of the nozzle cylinder 21 and the front-rear direction L1 coincide with each other.
The nozzle cylinder 21 communicates with the stem at the base end side inside the discharge head 20, and the discharge hole 21a is formed at the front end side. Therefore, by pressing the discharge head 20, the contents can be discharged forward from the discharge hole 21a of the nozzle cylinder 21.

(Outer container)
The outer container 4 is disposed above the discharge body 20 and the container 30 that houses the container body 2 and the discharge device 3 so as to be slidable along the front-rear direction L1. And an operation head 31 attached to the container 30.

The container 30 includes a first container 32, a second container 33, and a bottom lid 34.
As shown in FIGS. 1 and 2, the first container 32 is formed in a cylindrical shape surrounding the container body 2 from the outside in the radial direction. In the illustrated example, the first container 32 is formed in a rectangular shape in a cross-sectional view that is longer in the front-rear direction L1 than in the left-right direction L2. Thereby, the clearance gap of the front-back direction L1 can be ensured between the 1st container 32 and the container main body 2, and the slide movement to the front-back direction L1 of the container main body 2 and the discharge device 3 is enabled. .
However, the shape of the first container 32 is not limited to this case. For example, if a gap in the front-rear direction L1 can be secured between the container body 2 and the container body 2, for example, a square shape, a polygonal shape, or a circular shape in a cross-sectional view. Or oval.

  On the inner peripheral surface of the rear portion of the first container 32, vertically long convex ribs 35 projecting forward are formed. The convex rib 35 is formed over substantially the entire length of the first container 32 in the vertical direction, and has a width that fits between the two auxiliary ribs 13 along the horizontal direction L2.

  A portion of the convex rib 35 located below the inclined surface 12 a of the engaging rib 12 protruding from the support container 11 is in contact with the engaging rib 12 from the rear. Thereby, the convex rib 35 positions the rear position of the container main body 2. In addition, the part located above the inclined surface 12a among the convex ribs 35 protrudes further toward the front, and protrudes above the inclined surface 12a. As a result, the convex rib 35 can be disposed behind the operation projection piece 42 described later, and the vertical movement of the operation projection piece 42, in particular, the downward movement can be guided using the convex rib 35. . In addition, a slit-like groove 36 that opens upward and extends in the left-right direction L2 is formed at the upper end of the convex rib 35.

  As shown in FIG.1 and FIG.3, the 2nd accommodating body 33 is arrange | positioned above the 1st accommodating body 32, and is formed in the cylinder shape surrounding the discharge device 3 and the discharge head 20 from a radial direction outer side. In the illustrated example, the second container 33 is formed in a rectangular shape in a cross-sectional view longer in the front-rear direction L1 than in the left-right direction L2, similarly to the first container 32.

  The second container 33 is undercut fitted from above to the upper end of the first container 32, and is integrally combined with the first container 32. A restricting piece 37 that slightly protrudes rearward and restricts the upward movement of the operation head 31 is formed at the front portion of the upper end portion of the second container 33. A notch 38 that exposes the rear portion of the operation head 31 is formed in the rear portion on the upper end side of the second container 33. With this cutout portion 38, the operation head 31 can be easily moved downward.

  Further, an outer nozzle window (nozzle window) 39 that allows the nozzle cylinder 21 to pass therethrough is formed in the front portion of the second container 33. The outer nozzle window 39 is formed to have an elongated hole shape that opens largely downward from a position facing the nozzle cylinder 21 in the radial direction.

  As shown in FIG. 1, the bottom lid 34 is undercut fitted to the lower end portion of the first container 32 from below, and is integrally combined with the first container 32, and the first container 32. The lower end opening is closed.

As shown in FIGS. 1 and 2, the container 30 configured as described above is provided with a slide guide (guide member) 40 that guides the container main body 2 so as to be slidable along the front-rear direction L1. Yes.
The slide guide 40 is disposed on the inner side of the bottom cover 34 so as to face the left-right direction L2, protrudes toward the lower flange 15, and is formed to extend in the front-rear direction L1. The slide guide 40 is in contact with the lower flange 15 formed on the support container 11 from above and guides the lower flange 15 so as to be slidable in the front-rear direction L1. Thereby, the container main body 2 is slidable in the front-rear direction L1 in a state in which the container main body 2 is prevented from coming off upward.

As shown in FIG. 1, the operation head 31 is formed in a cylindrical shape with a peripheral wall portion 31 a and a top wall portion 31 b that covers the discharge head 20 from above. The peripheral wall 31a is fitted inside the second container 33 so as to be movable up and down. Under the present circumstances, the lower end part of the surrounding wall part 31a is arrange | positioned at intervals above the convex rib 35 formed in the 1st container 32. As shown in FIG. Thereby, the operation head 31 can be moved downward without interfering with the convex rib 35.
A stepped portion 41 that is in contact with the restriction piece 37 from below is formed in a portion located in the front of the connection portion between the peripheral wall portion 31a and the top wall portion 31b. Thus, the operation head 31 is restricted from moving upward by the restriction piece 37 and is prevented from coming off upward.

  The operation head 31 includes an operation projecting piece 42 that slides the container body 2 and the discharger 3 forward relative to the container 30 as the operation head 31 moves downward. An inner nozzle window (nozzle window) 43 that allows the nozzle cylinder 21 to pass therethrough and a pressing portion 44 that presses the ejection head 20 as the operating head 31 moves downward are provided.

  As shown in FIGS. 1 to 3, the operation protrusion 42 protrudes downward from a rear portion of the top wall portion 31 b. Specifically, the operation projecting piece 42 extends downward from the top wall portion 31 b while passing between the discharge device 3 and the first container 32 and the second container 33, and is between the two auxiliary ribs 13. It is formed so as to enter from above. The lower end portion of the operation protrusion 42 is formed so as to be inclined corresponding to the inclined surface 12a of the engaging rib 12, and is in sliding contact with the inclined surface 12a.

Thereby, the operation protrusion 42 can slide the engagement rib 12 forward as the discharge head 20 moves downward (see FIG. 4), and as a result, the container main body with respect to the outer container 4. 2 and the discharger 3 can be slid forward.
As described above, since the downward movement of the operation protrusion 42 is appropriately guided by the convex ribs 35 arranged behind the operation protrusion 42, the operation protrusion 42 is not subjected to unauthorized deformation such as rearward bending deformation or twisting. It is difficult to occur, and the engagement rib 12 can be surely pressed forward and slid. As shown in FIGS. 1 and 3, a cover cylinder 45 having a semicircular shape in plan view surrounding the discharge device 3 and the discharge head 20 from the outside in the radial direction is integrally formed in a substantially upper half of the operation protruding piece 42. ing.

  As shown in FIG. 1, the inner nozzle window 43 is formed in the front portion of the peripheral wall portion 31a. Specifically, the inner nozzle window 43 is formed over a range from a portion located below the step portion 41 to the lower end portion, and thereby opened downward. Therefore, when the operation head 31 is moved downward, the nozzle cylinder 21 can protrude outward from the outer container 4 through the inner nozzle window 43 and the outer nozzle window 39 (see FIG. 4).

  The pressing portion 44 projects downward from the top wall portion 31 b and is disposed above the ejection head 20 with a gap. As a result, the pressing unit 44 does not immediately press the ejection head 20 as the operating head 31 moves downward, but presses it with a slight time difference. Specifically, the pressing unit 44 is configured to cause the operation projection piece 42 to slide the container body 2 and the discharge device 3 forward with respect to the outer container 4 to cause the nozzle cylinder 21 to protrude from the outer container 4. Then, the pressing is started by contacting the ejection head 20 from above.

(First biasing member)
By the way, as shown in FIG. 1 and FIG. 2, the nozzle body 21 is moved to the container 30 by sliding the container body 2 and the entire discharge device 3 backward with respect to the container 30. There are provided two first urging members 51 and 52 for returning the first position to the original position.

  The first urging member 51 is connected to the mounting ring 53 having a C shape in a plan view and mounted on the support container 11 from the front, and extends along the left-right direction L2 and extends in the front-rear direction L1. A plate spring portion 54 that is elastically deformed, and is disposed at the upper end portion of the support container 11.

The leaf spring portion 54 has a middle portion in the left-right direction L2 coupled to a front portion of the mounting ring 53, and is curved toward the front from the coupling portion toward both end portions in the left-right direction L2. And the leaf | plate spring part 54 is attached to the 1st accommodating body 32 because both ends contact | abut the inner side of the 1st accommodating body 32. FIG. Thus, since the leaf | plate spring part 54 is curving, the 1st biasing member 51 is urging | biasing the container main body 2 and the discharge device 3 toward back via the support container 11. FIG.
The mounting ring 53 is sandwiched between the upper flange 14 and a positioning protrusion 55 protruding from the outer peripheral surface of the support container 11 and is positioned in the vertical direction.

  Similar to the first urging member 51, the first urging member 52 includes a mounting ring 53 and a leaf spring portion 54. It is energizing towards. The mounting ring 53 of the first urging member 52 is sandwiched between two positioning protrusions 55 projecting from the outer peripheral surface of the support container 11 and positioned in the vertical direction.

(Second biasing member)
As shown in FIGS. 1 and 3, the outer container 4 is provided with a second urging member 60 that urges the operation head 31 upward against the container 30.
The second urging member 60 is disposed inside the rear portion of the second housing 33 and between the peripheral wall portion 31 a of the operation head 31 and the first housing 32. The second urging member 60 includes two elastic arms 61 that are elastically deformed in the vertical direction, and a connecting piece 62 that is connected to the elastic arms 61.

  The elastic arm 61 has, for example, an upper end portion 61 a integrally connected to a lower end portion of a rear portion of the peripheral wall portion 31 a and a lower end portion 61 b connected to the connecting piece 62. The connecting piece 62 is inserted and locked into the groove portion 36 of the convex rib 35 formed in the first container 32. As a result, the upper end 61a and the lower end 61b of the elastic arm 61 are connected to the operation head 31 and the first container 32, respectively, and the operation head 31 is attached to the container 30 upward by its own elastic force. It is fast.

  In addition, the elastic arm 61 is arrange | positioned in the radial direction outer side of the cover cylinder 45 formed in the operation head 31, and the stable operativity is ensured by the contact with respect to the discharge device 3 being prevented. Further, the upper end portion 61a of the elastic arm 61 may not be integrally connected to the peripheral wall portion 31a of the operation head 31, and may be connected by being locked to the peripheral wall portion 31a via, for example, a connecting piece. .

(Use of discharge container)
Next, the case where the discharge container 1 configured as described above is used will be described.
In this case, as shown in FIG. 4, when the operation head 31 is pressed down with a fingertip or the like and moved downward, the lower end portion of the operation protrusion 42 is engaged while being in sliding contact with the inclined surface 12 a of the engagement rib 12. Since the rib 12 is pressed down from above, the container body 2 and the discharger 3 can be slid forward with respect to the outer container 4.
Thereby, the discharge head 20 can be slid forward and the nozzle cylinder 21 accommodated inside the outer container 4 is moved forward of the outer container 4 through the inner nozzle window 43 and the outer nozzle window 39. Can be projected.

At this time, as shown in FIG. 5, the leaf spring portions 54 of the first biasing members 51 and 52 are elastically deformed toward the front. The first urging members 51 and 52 urge the container body 2 rearward due to the elastic deformation of the leaf spring portion 54, but the operation protrusions 42 that have moved downward enter the rear of the engagement rib 12. The backward movement (restoration) of the container body 2 is suppressed.
Further, as shown in FIG. 4, the elastic arm 61 of the second urging member 60 is elastically deformed so as to be compressed in the vertical direction, and the pressing portion 44 is in contact with the ejection head 20 from above.

When the operation head 31 is further moved downward, the pressing unit 44 presses the discharge head 20, so that the contents can be discharged forward from the discharge hole 21 a of the nozzle cylinder 21 as shown in FIG. 6. it can. At this time, as described above, since the nozzle cylinder 21 has already protruded in front of the outer container 4, the contents can be discharged without any interference with the operation head 31 and the container 30.
At this time, the elastic arm 61 of the second biasing member 60 is elastically deformed so as to be further compressed in the vertical direction.

When the downward movement of the operation head 31 is released after the contents are discharged, the upwardly biased discharge head 20 moves upward to return to the original position, and the elastic arm 61 of the second biasing member 60 is restored and deformed. To do. Accordingly, the operation head 31 is pushed upward by the ejection head 20 and the elastic arm 61 to return to the original position.
Thereby, since the operation protrusion 42 also moves upward, the suppression of the backward movement of the container body 2 by the operation protrusion 42 is released. Accordingly, the plate spring portion 54 of the first urging members 51 and 52 is restored and deformed, so that the container body 2 and the discharge device 3 can be slid rearward with respect to the outer container 4. And the discharger 3 can be returned to the original position. As a result, as shown in FIG. 1, the nozzle cylinder 21 can be accommodated again in the outer container 4.

As described above, the forward movement operation of the discharge head 20 and the discharge operation of the contents can be performed simultaneously in a series of flows by one operation of moving the operation head 31 downward, so that the contents can be easily discharged. It is possible to improve the operability during discharge.
Moreover, after the contents are discharged, the first biasing members 51 and 52 move the container body 2 and the discharger 3 backward to naturally return the nozzle cylinder 21 to the original position. Can be improved.

  Moreover, since the nozzle cylinder 21 can be accommodated in the outer container 4 in the standby state before the contents are discharged, it is possible to prevent the nozzle cylinder 21 from interfering and to prevent the appearance from deteriorating. The design can be maintained.

  Further, when the lowering movement of the operation head 31 is released after the contents are discharged, the elastic arm 61 of the second urging member 60 urges the operation head 31 upward to move it upward. The operation head 31 can be smoothly returned to the original position without depending on the pushing-up. In addition, since the pushing load of the operation head 31 is reduced, the ejection head 20 can also be smoothly returned to the original position. By these things, operativity can be improved effectively.

  Further, since the slide guide 40 formed on the bottom lid 34 guides the sliding movement of the container main body 2, the slide is surely slid along the front-rear direction L <b> 1 without rotating the container main body 2 and the discharger 3 in the circumferential direction. Can be moved. Accordingly, the nozzle cylinder 21 can be accurately projected and retracted through the inner nozzle window 43 and the outer nozzle window 39.

  Furthermore, since the pressing portion 44 of the operation head 31 is disposed above the discharge head 20 with a space therebetween, when discharging the contents, the discharge head 20 is moved forward so that the nozzle cylinder 21 is attached to the outer container 4. After protruding forward, the contents can be discharged. Accordingly, the contents can be reliably discharged in front of the outer container 4, and the contents are not discharged while the nozzle cylinder 21 is moved forward. Therefore, the contents can be easily discharged to the target position.

  Further, for example, unlike the configuration in which the ejection head 20 is configured in a complicated manner and only the ejection head 20 is slid, only a simple configuration in which the engagement rib 12 is protruded from the support container 11 of the container body 2. Since the entire container body 2 and the discharger 3 are slid, the configuration can be easily simplified and the cost can be easily reduced.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, in the above-described embodiment, the pump-type discharge container 1 that discharges contents using the pump unit has been described as an example. In this case, the main container 10 of the container body 2 is, for example, blow-molded. Various configurations such as a container, a middle-plate sliding container, or a delamination container can be employed. Also, a former pump that discharges the contents in a foam state, a spray pump that discharges the contents in a mist state, or the like may be used.
Further, the discharger 3 is not limited to a configuration having a so-called pump mechanism, and may be a configuration having an aerosol mechanism (in this case, preferably a mountain cup is used as a mounting cap).

Moreover, in the said embodiment, the shape of the 2nd urging | biasing member 60 should just be able to urge | bias the operation head 31 with respect to the container 30, and the thing of a various shape is employable. The second urging member 60 is not essential and may not be provided. In this case, the operation head 31 is lifted and moved back to the original position by pushing up the ejection head 20 and pushing up the operation protrusion 42 by the inclined surface 12a of the engagement rib 12 based on the return of the container body 2. Just do it.
Further, the pressing portion 44 is configured to contact the discharge head 20 without any interval, and the forward movement of the container body 2 and the discharger 3 and the discharge of the contents are performed as the operation head 31 moves downward. It may be performed simultaneously.

Furthermore, although the inner nozzle window 43 is formed in the operation head 31 and the outer nozzle window 39 is formed in the second container 33, only at least one of the nozzle windows may be formed. In addition, although the container 30 was comprised by 3 parts, the 1st container 32, the 2nd container 33, and the bottom cover 34, it is not necessary to make each another, and it forms so that it may become 2 parts or 1 part. It doesn't matter.
Moreover, although the container main body 2 was comprised with the main container 10 and the support container 11, when it is set as the main container 10 with the engagement rib 12, for example, the support container 11 is unnecessary. Further, the engagement rib 12 may be formed not on the container body 2 but on the discharger 3 side.

DESCRIPTION OF SYMBOLS 1 ... Discharge container 2 ... Container main body 3 ... Discharger 4 ... Outer container 12 ... Engagement rib (engagement protrusion)
DESCRIPTION OF SYMBOLS 20 ... Discharge head 21 ... Nozzle cylinder 21a ... Discharge hole 30 ... Container 31 ... Operation head 39 ... Outer nozzle window (nozzle window)
40 ... Slide guide (guide member)
42 ... operation protrusion 44 ... pressing part 51, 52 ... first biasing member 60 ... second biasing member

Claims (4)

A container body for storing contents;
A discharger comprising a discharge tube that extends in the front-rear direction and has a nozzle cylinder formed with a discharge hole for discharging the contents at the front end, and is mounted on the container body so as to be able to be pushed down in an upwardly biased state; ,
A container for slidably moving the container body and the discharger along the front-rear direction, and an operation that is disposed above the discharge head and is mounted on the container so as to be movable downward with respect to the discharge head An outer container having a head, and
In the operation head,
The container body and the discharge device are brought into contact with the outer container by slidingly contacting an engaging protrusion formed on the container body or the discharge device as the operation head moves downward. On the other hand, an operation protrusion that slides forward,
A pressing unit that presses down the ejection head as the operating head moves downward,
In the outer container,
A nozzle window for allowing the nozzle body to pass through and projecting outward of the outer container as the container body and the discharger slide forward with respect to the outer container;
A discharge container, comprising: a first urging member that slides the container main body and the discharge device backward relative to the outer container to return the nozzle cylinder to its original position. In the discharge container according to claim 1,
The discharge container, wherein the outer container is provided with a second urging member that urges the operation head upward with respect to the container. The discharge container according to claim 1 or 2,
A discharge container, wherein the container is provided with a guide member for slidably guiding the container body along the front-rear direction. In the discharge container according to any one of claims 1 to 3,
The pressing portion is disposed above the discharge head with a space therebetween, and the operation protrusion slides the container body and the discharger and then starts pressing in contact with the discharge head. A discharge container.

Images