JP2544009Y2 - Air action toys - Google Patents

Description

[Detailed description of the invention] (Industrial application field) The present invention sends compressed air from the inside of the air board to the unit toy attached to the hole on the air board, and the air blows out from the hole of the air board. The present invention relates to an air action toy that causes a toy to perform an action.

(Prior Art) The present applicant has proposed a structure for operating a toy detachably attached to a base having an air duct therein as an air action toy in Japanese Utility Model Application No. 2-38290.

(Problem to be solved) The air blower attached to the air board of the above invention is merely a power source for sending air to the air duct in the air board, and the air board itself controls the flow rate of air. It was not possible to control the movement of each toy arbitrarily.

Therefore, in the present invention, it is an object to provide a mechanism for controlling the movement of each toy by providing the air blower itself with a fun as a toy, providing a control mechanism on the air board.

(Means for Solving the Problems) A blower for blowing air through the inside of the base is attached to the base in a plurality of holes provided on the surface of the base, and the base is inserted from each of the plurality of holes. In the toy that guides the airflow blown from the inside into the unit toy through the junction of the unit toy and operates the unit toy with the airflow, the opening / closing mechanism includes a plurality of airflows leading to the plurality of holes. When one of the air passages is gradually and fully closed from full open, the other air passage is connected to the shutter member provided on the base surface and the shutter member gradually and fully open from fully closed. An air action toy comprising an operation unit, wherein the operation of the operation unit causes the shutter member to operate to adjust the opening and closing of the air flow to the plurality of holes.

In addition, the base is provided with an air outlet for sending out air and the same hole as the hole provided on the surface of the base, and is independent of the base having a built-in blower capable of mounting a unit toy in the hole. It is an air action toy having a unit toy.

In addition, it is joined to any of the multiple holes provided on the base surface, and airflow from inside the base is taken in through the joint,
In a unit toy that operates the operating part by air flow,
An air action toy having an exhaust port for exhausting air after operating the operation part of the unit toy to the outside of the unit toy, in the same shape as the shape of the hole of the base.

(Operation) According to the above configuration, each unit toy is joined to each hole of the base, and an air flow is blown from the blower into the base. By opening and closing the opening surfaces of the holes, the amount of air flowing into each hole is adjusted, the amount of air to the unit toys connected to each hole is controlled, and the operation speed of each unit toy is controlled.

By mounting a unit toy having a built-in blower on the base, air can be blown to the base, and each unit toy aligned with each hole is operated. Further, another unit toy can be mounted and operated in a hole of the unit toy incorporating the blower.

In addition, the air outlet of the air after operating the operating part of the unit toy is made the same as the joint hole of the base, and another unit toy can be joined to the exhaust port, and the air flow used once is re-used. Use.

(Example) Hereinafter, the air action toy of the present invention will be described in detail with reference to the drawings.

FIG. 1 is an overall perspective view of the present air action toy, and FIG. 2 is an external perspective view of a base without the unit toy.

The base 1 is a plastic rectangular box having a rectangular notch at the right rear corner and a rectangular box at the rear, one step higher. A compressed air is inserted into the rectangular notch on the right rear side. A docking hole 2 is provided on the right side.
Is docked with the fan unit car 20.

A rectangular column-shaped boss hole 3 is opened at the center and three places on the left and right sides of the front flat portion of the base, and a short cylindrical boss hole 4 is opened on the left flat surface behind the base. Boss hole 3 in front
The helicopter 30 and the gas station 40 are detachably set as action units, and the rear boss hole 4
, The tower 50 is set detachably. Further, a shutter operation lever L is provided at the center of the rear of the base, and a siren 60 is fixed to the base on the right side.

FIG. 3 shows an external perspective view of the fan unit car shown in FIG.
The fan unit car 20 is a bongo car toy, and the tire 21
The front and rear wheels rotate freely, and you can play by pushing with your hand. Further, a power switch 22 for a blower fan, which will be described later, is provided on the right side, and the driver's seat and the rear center of the ceiling are recessed into a cylindrical shape. A boss hole 24 is formed in the vehicle body, and a docking nozzle 25 protrudes rearward at the lower center of the rear side of the vehicle body.

FIG. 4 shows a sectional view of the fan unit car. A duct 26 is provided at the lower center of the inside of the fan unit car 20 so as to communicate with the rear docking nozzle 25 and the boss hole 24 in the front ceiling. A blower fan 27 is provided in 26, and the blower fan 27 is mounted on a rotating shaft of a motor 28.

By opening and closing the power switch 22, the power of the battery 29 provided inside is supplied to the motor 28, the blower fan 27 is rotated to take in the air flowing into the blower fan 27 from the lower side of the duct, and the rear docking nozzle 25 and The air is sent out to the upper boss hole 24.

The water tower shown in Fig. 1 as an action toy in the boss hole 24
70 is detachably attached. Further, a helicopter 30 or a gas station 40 can be attached to the boss hole 24.

FIG. 5 is a perspective view from the rear side showing the internal structure of the base. The internal boundary wall 5 between the front short rectangular part and the rectangular part behind the shutter operating lever L has a uniform width in the vertical direction. Are provided vertically at four locations, and the slit width of the slit 6 is smaller than the width of the lattice member 7 sandwiched between the slits.

A shutter member 8 is slidably provided on the slit 6 in the rear rectangular portion. The shutter member 8 is in the shape of an unused needle of a stapler, the height is smaller than the depth inside the square portion, and the height is smaller than the height inside the square portion behind the base. The base 1 slides and slides on the boss hole 4 and the slit 6.

FIG. 6 shows a bottom view of the shutter member and the inner boundary wall. The length 1 of the shutter member in the sliding direction is a length that closes the boss holes 4 and 4 of the tower 50 and the siren 60 and has a margin 2r. . On one side of a shutter member 8 that slides on the slit 6 portion of the internal boundary wall, four slits 9 are provided vertically in the same width as the slit 6, and the width of the grid member 10 is also changed to the width of the grid member 7 of the internal boundary wall. Is the same as the width of The shutter member 8
An elongated hole 12 is formed in the center of the ceiling member 11 along the lattice direction, and an elongated hole 13 is opened vertically behind the center of the elongated hole 12.

Assuming that the slit width is k1 and the lattice member width is k2, k1 is smaller than k2, k1 is greater than r, and if the diameter of the boss hole 4 of the tower 50 and the siren 60 is d, the lattice member width k2 is r +
It is larger than d. Assuming that the total length of the long hole 12 is 2s, s is larger than k1 and smaller than k2.

A boss (not shown) having a round hole 14 with a short width of the long hole 12 is provided on the base at the center of the long hole 12 at a position where the shutter member 8 is aligned with the slit portion of the internal boundary wall. A shutter operation lever L is rotatably mounted on the base surface, and the shutter operation lever L and the shutter member 8 are provided on the boss portion in a round hole of the boss portion.
It is connected by a cam shaft 15 via.

As shown in FIG. 5, a cam shaft 15 is fixed to the lower surface of the shutter operating lever L through the round hole 14,
A lug plate 16 is suspended from the inside of the shutter member 8 at 15,
A boss 17 is provided on the long hole 13 side of the lug plate 16, the boss 17 is in sliding contact with the outer end side of the long hole 13, and the other end of the cam shaft 15 is provided on the floor plate of the base 1 (not shown). It is rotatably supported by the boss.

As described above, when the shutter member 8 moves the shutter operation lever L rotatably provided on the surface of the base 1 to the right or left, the cam shaft 15 fixed to the shutter operation lever L rotates. Then, a notch 17 provided at an end of a lug plate 16 provided laterally on the cam shaft 15 slides on the long hole 13 of the shutter member to slide the shutter member 8 left or right.

FIG. 7 is a plan view showing the movement of the shutter operation lever. When the shutter operating lever L is facing the front, the shutter member 8 is at the center position, that is, the position where the shutter member and the slits 9 and 6 of the internal boundary wall are aligned.

In this state, the position of the shutter operation lever L is set to C.
The maximum left and right swing angle of the lever is set to 50 degrees, and the lever positions at that position are A and E.
Degree positions are B and D, and 10 degrees inward from A and E positions.
The positions of the degrees are F and G.

At the positions A, C, and E of the shutter operation lever L, there are irregularities on the sliding surfaces of the lever and the base, and the shutter operation lever L can be formed at each position.

FIG. 8 shows the air flowing into each hole due to the movement of the shutter operation lever. When the lever is at the position C, the shutter member is at the position shown in FIG. 6, and the left and right boss holes 4, 4 are closed.
The internal boundary wall 5 and the slits 6 and 9 of the shutter member 8 completely match, and the slit opening area is the largest.

In this state, the inflow air from the fan unit car has the boss holes 4 and 4 closed, so that all the inflow air passes through the inner boundary wall 5 where the slits are open and the three boss holes 3 on the front side. Through the air flow path that exits from the outside. Therefore, if a unit toy is connected to each boss hole 3, the unit toy is operated.

Next, when the lever is moved to the position B, the camshaft 15 rotates, and the notch 17 pushes the long hole 13 of the shutter member to the right, and slides the shutter member to the left side on the opposite side to the lever by a distance r, The end of the shutter member is located at the leftmost end of the boss hole 4 of the tower 50, and the open area of the slits 6 and 9 is slightly reduced.

In this state, although the slit of the internal boundary wall 5 gradually narrows with the movement from the lever position C to the lever position B, there is no change in the air flow path that flows out only from the three boss holes 3 on the front side. However, the amount of air flowing out of each boss hole is smaller than the lever position C.

When the lever is further turned from the position B to the position F, the bocce 17 pushes the long hole 13 further right to slide the shutter member 8 to the distance k1, and from the left end of the shutter member 8, the boss hole 4 of the tower 50 is opened. , And the slits 6 and 9 are completely sealed.

In this case, the boss hole 4 on the tower side is closed from the position B to the position F until the half opening, and the slit of the inner boundary wall is changed from the half open state to the fully closed state. Accordingly, the air flow to the boss hole 3 on the tower side is opened while the air flow path to the boss hole 3 on the front side is narrowed. Move.

When the lever is turned to the left maximum position, the shutter member 8 slides for a distance of r + d, the boss hole 4 of the tower 50 is fully opened, and the slit portion is wider than the slit width, so the sealing member is still closed. Remains.

Here, since only the boss hole 4 of the tower is fully opened, the air flow path is only the tower, and the tower 50 operates vigorously.

Conversely, when the lever is moved to the right, the slit portion gradually closes, and the boss hole 4 of the siren 60 opens.

By gradually operating the shutter operation lever as described above, one of the air passages leading to the plurality of holes is gradually and completely closed from full open, and the air passage leading to the other holes is completely closed. Fully open gradually from closed. Therefore, there is no shortage of inflow air for operating the unit toys, and no operation of the unit toys is stopped.

The airflow flowing into the base from the fan unit car 20 detachably attached to the docking hole 2 by the operation of the shutter operation lever L in this manner depends on the position of the shutter member 8 and the slits 6 of the internal boundary wall. The air flows in accordance with the open / close state of the boss hole 4, and the air inflow state corresponds to the opening state of the shutter in FIG.

FIG. 9 shows the internal structure of the helicopter 30. A doll is provided in the front of the helicopter cockpit as a doll mounting part 31 for placing dolls. Refueling holes are provided on both sides of the body of the helicopter 30.
An opening 32 is provided, and a short cylindrical joining portion 33 that fits into the boss hole 3 is provided at the bottom, and a round hole 34 is opened at the center of the joining portion. When the joint 33 of the helicopter is fitted into the boss hole 3, the airflow from the inside of the base flows in the body of the helicopter 30 from the bottom toward the inside, and the upper part of the body and the inner plate
The air is blown to a fan 37 which is axially mounted inside a body on a rotating shaft 36 rotatably supported vertically to 35. Then, the air flow rotates the fan 32, rotates around the rotary blade 38 via the rotary shaft 36, and exits through the exhaust hole 39 on the upper side of the body.

Further, the refueling hole 32 is opened toward the fan 37, and a refueling hose 42 of a gas station 40 described later can be inserted. The nozzle at the tip of the refueling hose 42 contacts the fan 37 to rotate the fan 37. Can be stopped.

As shown in FIG. 1, the gas station 40 has a decoration in which a transparent cylindrical outer drum 41 is laid sideways on a rectangular body, and a refueling hose 42 is provided from a side of the rectangular body.
A nozzle is attached to the tip.

FIG. 10 shows the internal structure of the gas station 40. A short cylindrical joining portion 43 is provided at the bottom to be fitted to the boss portion, and when fitted to the boss portion 3 of the base, the joining portion 43 is provided. Opening 44
More air flows from inside the base.

Here, at the bottom of the rectangular body, a switch plate 45 for closing the opening 44 of the joint 43 is rotatably supported by a shaft erected on the bottom and slidably contacts the bottom. When the switch plate 45 is slid to open the opening 44, air flows into the inside, and when the switch plate 45 is closed, air cannot flow.

A small-diameter internal drum 46 is provided coaxially inside the external drum 41, and a narrow hole 47 extending in the rearward direction on the lower surface of the external drum 41 in contact with the upper part of the rectangular body extends leftward and rightward. A plurality of air vents 48 are provided in a slit shape on the upper front side of the external drum 41. External drum 41 and internal drum 46
Between them, foam balls 49 of different colors are inserted, the diameter of the foam balls 49 is larger than the small hole 47 and the punched hole 48, and is larger than that between the outer drum 41 and the inner drum 46. small.

Therefore, the air flowing from the opening 44 of the joining portion 43 vigorously flows from the narrow hole 47 on the lower side of the external drum 41 in the rearward direction of the circumference in the external drum, and the foamed ball 49 moves upward rearward with this force. It is wound up and lifted up to the front of the external drum along the inside of the external drum 41 as it is. Here, the inflow air flows out through the hole 48, but since the foam ball 49 is larger than the small hole 47 and the small hole 48, it cannot escape from these holes. It is blown up by the air vigorously flowing from 47 and rotates inside the external drum 41 along the circumference. The foamed ball 49 can be replaced with any other material that can be blown up by air, such as colored wings.

This state can be seen from the outside because the external drum 41 is transparent, and the foam beads 49 are variously colored so that they are very beautiful, and it looks as if the gas station gauge is moving.

Next, a sectional view of the tower 50 is shown in FIG. 11, and a circular seat 52 is fixed to the lower end of the long and transparent cylindrical body 51 so as to fit into the boss 4 of the base. An opening 53 smaller than the inner diameter of the cylindrical body 51 is provided at the center.

An elevator 54 is placed in the cylindrical body 51, and the elevator 54 is provided with a column having a diameter slightly smaller than the diameter of the disk and substantially the same height as the diameter at the center of the upper surface of a disk slightly smaller than the inner diameter of the cylinder. And the upper side of the cylinder is dome-shaped.
In the center of the elevator 54, through holes 55 are provided vertically.

The air flow from the opening 53 acts in a direction to push up the disk of the elevator 54, and the air flow lifts the elevator 54 while flowing along the inner wall of the cylinder from the periphery of the disk. Here, the through hole 55 at the center of the elevator serves as a bypass auxiliary hole for the airflow flowing therearound, thereby reducing the speed of the elevator 54.

A heliport 56 is attached to the upper end of the cylindrical body 51. The heliport 56 is a disk having a diameter larger than that of the seat 52. The center portion of the disk is provided with the same boss portion 57 as the boss portion 4 of the base, and a boss hole 59 is opened at the center of the boss portion. .

The cylindrical body 51 is fixed below the boss portion 57 of the heliport, and a plurality of ribs 58 are provided radially on the inner wall on the back side of the boss portion 57 as locking pieces when the elevator 54 rises in the axial direction. . Thus, even if the elevator 54 abuts on the rib 58, the flow of air passing around the elevator 54 can pass between the ribs 58 and escape to the boss hole 59 of the heliport 56.

If the helicopter 30 is attached to the boss portion 57 of the heliport 56, the air flowing out of the boss hole 59 of the boss portion 57 rotates the rotor 38 of the helicopter.

Here, if there is little air flowing from the boss portion of the base, the elevator 54 cannot be pushed up, and gradually descends due to its own weight.

FIG. 12 shows a cross-sectional view of the siren 60. The siren 60 has a round hole 62 opened in the center of a seat 61 fitted and fixed to the boss portion of the base, and the seat 61 is provided with an inclination from the outer peripheral side toward the round hole 62, A transparent truncated cone 63 is provided in 61, and the inside of the truncated cone 63 is hollow, and one foam ball 64 larger than the round hole 62 is inserted inside, and a whistle mechanism is provided at the upper part of the truncated cone. 65 are provided.

Therefore, the air flowing from the round hole 62 of the seat 61 blows the foam balls 64 up and down on the round hole 62, and the state can be seen because the truncated cone 63 is transparent, Goes out through the whistle mechanism 65 above the siren.

The whistle sounds when air passes through the whistle mechanism 65, but the movement of the foam ball 64 closes the round hole 62 and
The amount of air entering 65 changes constantly, and the sound of the whistle changes constantly and sounds like a siren.

A larger change in the amount of air can be performed by operating the shutter operation lever L of the base.

FIG. 13 shows a sectional view of the water discharge tower 70. A rotatable impeller 72 is provided rotatably inside a horizontally disposed transparent short cylinder 71, and the rear end of the fire nozzle 74 is attached to a holding portion 73 provided on the outer peripheral front side of the short cylinder 71 so as to swing up and down. is there. The lower part of the short cylinder 71 is a seat 75, and the joint part that fits into the boss part is at the bottom of the seat base.
An opening 77 is provided at the center of the joining portion, and the opening 77 is directly guided into the upper short column 71.

Then, the air flow guided into the short short cylinder 71 rotates the impeller 72 and flows out of the slit group 78 on the upper peripheral wall of the short cylinder 71 to the outside.

An L-shaped switch member 79 is pivotally mounted on the back of the seat 75 at the waist of the L-shape, and is slidably provided on the seat 75. Abuts on the outer circumference, impeller 72
Stop the rotation of.

As described above, the joint of each unit toy is common, and the boss hole 3 has a helicopter 30 and a gas station.
The helicopter 30, gas station 40 and water tower 70 can be detachably connected to the boss 57 of the heliport of the tower 50 and the boss hole 24 of the fan unit car 20. .

(Effect) Since the air action toy of the present invention can control and distribute the inflow air from the fan unit car mounted on the base, the air flow that leads to a plurality of holes at any operation position of the shutter operation lever. When any one of the roads is opened, the air flow passage leading to the other hole is closed, so that each unit toy operates normally, and the inflow of air is small, and the operation does not fall together.

In addition, since the fan unit car has the same hole as the base and air comes out, it works when other unit toys are joined, and it is an interesting unit toy not only as a blower but also as a toy .

Further, since the operation stopping means is provided for each toy, it is possible to play by controlling the movement of each toy.

In addition, another unit toy can be connected to the air outlet of the unit toy, and the unit toy can be connected in a double manner.

[Brief description of the drawings]

FIG. 1 is an overall perspective view of the air action toy, and FIG. 2 is an external perspective view of a base of the air action toy with the unit toy removed. FIG. 3 is an external perspective view of the fan unit car, and FIG.
The figure shows a sectional view of the fan unit car. FIG. 5 is a rear perspective view showing the internal structure of the base, and FIG. 6 is a bottom view of the shutter member and the internal boundary wall.
FIG. 7 is a plan view showing the movement of the shutter operation lever, and FIG. 8 shows the air flowing into each hole due to the movement of the shutter operation lever. 9 shows the internal structure of a helicopter, FIG. 10 shows the internal structure of a gas station, FIG. 11 shows a sectional view of a tower, FIG. 12 shows a sectional view of a siren, and FIG. 13 shows a sectional view of a water discharge tower. 1 ... base, 2 ... docking hole, 3/4 ... boss hole,
8 shutter member L shutter operation lever
20 ... fan unit car, 30 ... helicopter, 40 ...
... gas station, 50 ... tower, 60 ... siren,
70 …… Water Tower

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI Technical display location A63H 29/16 A63H 29/16

Claims (3)

(57) [Scope of request for utility model registration] An air blower for blowing air through the inside of the base is attached to the plurality of holes provided on the surface of the base, and air is blown from the inside of the base from each of the plurality of holes. Guiding the air flow into the unit toy through the joint of the unit toy, and operating the unit toy with the air flow, opening and closing a plurality of air flow paths communicating with the plurality of holes inside the base. An opening / closing mechanism is provided.When the opening / closing mechanism gradually and fully closes one of the plurality of air flow paths from the plurality of air flow paths to the plurality of holes, the other air flow path changes from the fully closed state. A shutter member that is gradually fully opened, and an operation unit that is connected to the shutter member provided on the base surface, wherein the operation of the operation unit causes the shutter member to operate and reduce an air flow rate to the plurality of holes. Open and close An air action toy characterized by: 2. An air blower for blowing air through the inside of the base to a plurality of holes provided on the surface of the base. The blower is blown from the inside of the base through each of the plurality of holes. Guiding the air flow into the unit toy through the junction of the unit toy, and operating the unit toy with the air flow, comprising: an air outlet for sending air to the base; and An air action toy having a hole identical to the hole provided, and having a unit toy independent of the base having a built-in blower in which a unit toy can be mounted. 3. A unit toy which is joined to one of a plurality of holes provided on a surface of a base, takes in an air flow from the inside of the base through a joint portion, and operates an operating portion by the air flow. An air action toy, wherein an exhaust port for exhausting the air after operating the operation section of the above to the outside of the unit toy is provided in the same shape as the shape of the hole of the base.