JP2009509803A5 - - Google Patents

Description

  FIGS. 1a and 1b show a pictorial wireframe and three-dimensional representation of a floating platform 10 according to the present invention for supporting a portable self-powered electric lamp 11 or other object in the air. The floating platform 10 constitutes a hollow support structure that is strong enough to withstand bumps and the like without bursting, while supporting the lamp 11 when filled with helium gas. In the meantime, it is made of a semi-rigid, gas-impermeable plastic material that can float in space. The valve seat 12 is formed on the lower surface of the floating platform 10 to adapt to the corresponding valve seat 13 formed on the lamp 11 via the adapter 14, and different objects are connected to the floating platform 10 in a sealing manner. Allow different seating to be done.

  Patent document 1 discloses a balloon action toy that moves up and down, which includes a package filled with a gas that is lighter than air, and the package alternates up and down alternately to the limit.

  2a and 2b show a pictorial wireframe representation of the lamp 11, which is a gas connector 16 connected to a floating platform, as shown in FIG. 1b and more particularly in FIGS. 5a and 5b. Surrounded by an outer envelope 15 adapted to the gas filling mechanism connected by. The envelope 15 also encloses an electrical circuit (not shown) for operating the lamp, and of course the lamp itself (also not shown). A battery housing 17 for accommodating one or more batteries may be inserted into a shaft hole 18 whose lower end is sealed by a lower sealing cap 19 in the housing of the outer casing 15. For purposes of explanation and appended claims, the envelope 15 and its accompanying parts constitute an object to be supported by the floating platform 10. It is clearly recognized that other equipment can be contained within the package 15, and as noted above, different packages with different accessories are coupled to the floating platform 10 via appropriate adapters. Provided for. In this configuration, the lamp is mounted on the upper end of the shaft hole 18 to illuminate the interior of the floating platform 10, which is balloon-shaped as shown. The surface layer is formed of an optical transmission material. However, according to another embodiment, when the floating platform 10 is set to float, the lamp is placed at the lower end of the shaft hole 18 for illumination downward. This type of embodiment is described in more detail below with reference to FIG. In yet another embodiment, electrical connections can be formed at both ends of the shaft hole 18 to allow lamp connection at either end.

  The gas connector 16 is fluidly connected to a tube 22 having upper and lower ends opened in the floating platform 10 in order to fluidly connect the gas filling mechanism to the floating platform 10. A removable sealing cap 23 is fixed to the lower end of the tube 22 and prevents gas leakage from the gas filling mechanism. It should be noted that the drawing shows a gas filling mechanism in the form of an exploded tube 22 projecting from the lower part of the outer envelope 15. In practice, however, the tube 22 is completely contained within the outer envelope 15 and the envelope so that only the sealing cap 23 can be removed when purge gas is required from the floating platform 10. Approach from the underside of 15. For this purpose, the release valve 24 diffuses gas from the floating platform 10 through the open end of the tube 22 after removal of the sealing cap 23. The gas connector 16 extends through the enclosure 15 so that when connecting the object 11 to the floating platform 10, the latter includes helium at a controlled pressure to float the attached object and hang it in the air. Filled with gas like. The upper sealing cap 20 also serves to seal the gas filling mechanism from the electronics associated with the lamp, as well as the battery housing 17 and the lamp housing 17 and the lamp itself, and thus in contact with the gas. Avoid the danger of sparks by.

  8a and 8b show different perspective views of the floating platform and the original object in place. In particular, the gas inlet and discharge valve shown on the opposite side of the outer envelope 15 can be seen in the two figures.

  FIG. 12a is a pictorial representation, and FIG. 12b is a pictorial exploded half-sectional view showing a disposable device 60 according to another embodiment that floats when the sealed gas unit is opened. In many respects, the device 60 is structurally similar to the device 10 described above with reference to FIGS. 1, 4 and 8, and includes a buoyant balloon platform 61 to which an object 62 is attached. However, unlike the first embodiment, the object 62 includes a seal unit (not shown), which is released by opening a gas seal 63 that is accessible from the outer surface of the object 62. Gas is put in. As clearly shown in FIG. 12b, the object 62 is placed in a battery housing 17 that is sealed at its lower end and shown in an airspace relationship to the axial hole 18 in the outer envelope 64 of the object 62. ing. Also shown more clearly is the tube 22 that engages the gas connector 16 of the gas filling mechanism and the opening 35 of the floating platform 10.

[0057]
[Figure 1]
2 is a pictorial wireframe and three-dimensional representation of a platform for freely supporting an object in space according to a first embodiment of the present invention;
[Figure 2]
FIG. 5 is a pictorial wireframe representation of a self-powered electric lamp enclosed within an outer envelope corresponding to a gas connector coupled to a floating platform.
[Fig. 3]
3 is a pictorial wireframe representation of the components of the lamp and gas connector shown in FIGS. 2a and 2b.
[Fig. 4]
2 is an exploded pictorial wireframe representation of the relevant components of a floating platform and gas connector.
[Figure 5]
It is a different perspective view of the component of a gas connector.
[Fig. 6]
FIG. 2 is a different perspective view of a gas container according to a first embodiment, suitable for filling a floating platform with helium gas.
[Fig. 7]
FIG. 6b is a different perspective view of the gas container shown in FIGS. 6a and 6b when connected to a gas connector during use.
[Fig. 8]
FIG. 3 is a different perspective view of a floating platform and attached objects.
FIG. 9
FIG. 9 is a pictorial representation of the use of a floating platform to support an object in the air.
FIG. 10
It is a pictorial representation showing a gas container according to a second embodiment.
FIG. 11
FIG. 2 is a pictorial representation of the entire device integrated with a buoyant case having a hollow wall and a pictorial representation showing breakage of the hollow wall.
[12]
FIG. 2 is a pictorial representation showing the entire disposable device floating when the seal gas device is opened, and a pictorial exploded half-section showing the details.

10 platforms
11 Lamp
15 Package
16 Gas connector
17 Battery housing
21 Pressure valve
25 Gas container
32 Gas outlet
33 Gas inlet
40 Gas container
50 watches
60 Disposable devices
61 Platform
62 objects

Calibration of the adjustable pressure valve 21 is based on the following principle. The air density ρ _air must be equal to the average density ρ _total of the support and the object.

The average density ρ _total l of the support structure and the object is given by the following equation.

here,
M _HE = helium mass
M _Object = mass of the object
M _total = total mass of support structure and object
V _Total = total volume of support structure and objects.

  It can be seen that the ambient pressure (P), effective volume (V) of helium in the hollow support structure is given by:

Claims (7)

  An object adapted to float in the air when filled with a gas having a specific gravity lower than air without requiring a anchoring position connected to the ground, said object being connected to a pressure regulating means A hollow housing having an inlet, the inlet for prefilling the hollow housing via a one-way valve capable of preventing the gas from leaking from the hollow housing The pressure adjustment means in the housing to ensure that only the levitation force of the housing is balanced with the weight of the object without additionally supplying the gas to the hollow housing. An object for adjusting the pressure of the gas.   The object according to claim 2, wherein the object includes a battery.   9. An object according to any one of claims 1 to 8, wherein the inlet is suitable for coupling to a sealing unit containing gas, the gas being accessible from the outer surface of the object. An object that is released by opening. A method for freely supporting an object in the air without requiring a anchoring position connected to the ground, the method comprising: a hollow housing filled with a gas having a specific gravity lower than that of air. Attaching to a supporting structure having
Pre-filling the hollow housing via a one-way valve capable of preventing the gas from leaking from the hollow housing;
Adjusting the pressure of the gas in the casing so that only the levitation force of the casing is balanced with the weight of the support structure and the attached object without additionally supplying the gas to the hollow casing. A method comprising:   20. A method as claimed in any one of claims 16 to 19, wherein adjusting the pressure of the gas in the housing is to supply the gas at a suitable pressure to generate the levitation force. A method comprising setting a calibrated pressure gauge as a function of the weight of the attached object according to the known weight of the attached object.   20. The method according to any one of claims 16 to 19, wherein adjusting the pressure of the gas in the housing is configured to measure an ambient temperature and adjust a gas mass in the housing. Adjusting the pressure of the gas in response to the ambient temperature measured.   20. A method according to any one of claims 16 to 19, wherein adjusting the pressure of the gas in the housing comprises adjusting the effective volume of the hollow support structure.