RU2007108786A

RU2007108786A - MOVABLE ENERGY CONSUMPTION DEVICE

Info

Publication number: RU2007108786A
Application number: RU2007108786/12A
Authority: RU
Inventors: Уолтер Р. ЭВАНИК (US); Уолтер Р. ЭВАНИК; Тим ЛОНГ (US); Тим ЛОНГ
Original assignee: ПАУЭРПАЛС ТЕКНОЛОДЖИЗ, Эл.Пи. (US); ПАУЭРПАЛС ТЕКНОЛОДЖИЗ, Эл.Пи.
Priority date: 2004-08-10
Filing date: 2005-03-30
Publication date: 2008-09-20
Also published as: CN101001550A; CA2576509A1; KR20070044041A; WO2006022871A3; US20060032076A1; AU2005278112A1; WO2006022871A2; JP2008510444A; AU2005278112B2; KR100841921B1; EP1781136A2; BRPI0515020A

Claims

1. A method of creating a movable energy-consuming device, comprising the steps of:

the formation of the hull with associated energy-consuming load, and <in action> loads there are energy losses in the system;

forcing the energy-consuming load to achieve the desired operating level by using a power source located outside the chassis;

separation of the external power source from the energy-consuming load after reaching the desired operating level;

maintaining the desired operating level of the energy-consuming load by using a power source located inside the cabinet to compensate for energy loss in the system, thereby creating a relocatable energy-consuming device.

2. The method of claim 1, further comprising the steps of:

linking at least one heating element to the body part <and use> as an energy-consuming load;

forcing at least one heating element to achieve a desired temperature representing a desired operating level by connecting an external power source to it;

separating the external power source from the at least one heating element after the at least one heating element reaches the desired temperature; and

automatically forcing the inside of the power source to connect to at least one heating element to provide enough energy to maintain the desired temperature only after disconnecting the first power source.

3. The method of claim 2, further comprising the steps of:

use of alternating current as an externally located power source, and

the use of galvanic (battery) cells as located inside the power source.

4. The method according to p. 3, in which the step of linking at least one heating element to the housing part further comprises the steps of:

connection, with the possibility of disconnecting, located externally from the AC power source to the AC heating element associated with the housing part, for forcing the AC heating element to heat to the desired temperature; and

automatic linking of the DC heating element to the housing for heating using internal galvanic (battery) cells to provide enough energy to maintain the desired temperature only after separating the external AC power source from the AC heating element.

5. The method of claim 2, further comprising the steps of:

the use of direct current as an external power source, and

the use of galvanic (battery) cells as located inside the power source.

6. The method according to p. 5, in which the step of linking at least one heating element to the housing part further comprises the steps of:

the formation of one DC heating element in the housing;

rectifying the current at the output of an external AC power source to obtain a direct current output supplied to one direct current heating element to achieve a desired temperature, and

automatic connection of the inside of the galvanic (battery) cells to one DC heating element to provide only enough energy to maintain the desired temperature only after disconnecting one heating element from the DC output received after rectification of the current from an external AC source.

7. The method of claim 1, further comprising the steps of:

placing a normally closed electrical switch between at least one energy-consuming load and a second power source located inside

automatic opening of the electrical switch when connecting an external power source to at least one energy-consuming load to prevent the internal power source from being connected to at least one energy-consuming load.

8. The method of claim 7, further comprising the steps of:

providing an electrical connector for insertion into an outlet connected to the body portion of the energy-consuming device for attaching an external power source to the energy-consuming load, and

the use of an electrical plug, when inserted into a power outlet, to automatically open the electrical switch and to prevent the internal power supply from being connected to at least one energy-consuming load.

9. The method of claim 8, further comprising the step of automatically charging an internal power source when an external AC power source is connected to a power-consuming load.

10. The method of claim 6, further comprising the steps of:

placing an electrical switch between one direct current heating element and an internal galvanic (battery) element, and

automatic opening of the electric switch when connecting the DC output of the external power source to one heating element of the direct current to prevent the inside of the galvanic (battery) cells being connected to the same heating element of the direct current.

11. The method of claim 10, further comprising the steps of:

providing an electrical connector for insertion into an outlet connected to the housing of the power-consuming device for connecting an external power source to a single DC heating element; and

the use of an electrical connector, when inserted into an outlet, to automatically open the electrical switch and to prevent the inside of the galvanic (battery) cells from being connected to a single DC heating element.

12. The method of claim 11, further comprising the step of automatically charging the battery cells located within the battery when an external power source is connected to a single DC heating element.

13. The method according to claim 1, further comprising the step of connecting a control circuit between the internal power source and the power-consuming load only when the device is movable, to automatically maintain the desired operating level, to maintain the power source located inside the power supply, and also to extend the service life power consuming load.

14. The method of claim 13, further comprising the steps of:

generating a feedback signal using a control circuit representing the current load levels at a given point in time; and

using the received feedback signal to reduce the input power directed to the energy-consuming load from the internal power source to a value sufficient only to compensate for the losses in the system, in order to save, therefore, electrical energy by maintaining the desired operating load level using reduced input power.

15 . The method of claim 14, further comprising the steps of:

connecting an electronic mains switch between the power-consuming load and the internal power supply, and

switching the electronic network switch to the “On” and “Off” positions using pulse modulation signals in time to reduce the input power in such a way as to supply only a sufficient amount of energy to the energy-consuming load, in order to maintain the desired operating level.

16. The method according to claim 1, further comprising the step of using a heating element of one of the selected devices: a device for styling hair or an iron, as an energy-consuming load.

17. The method of claim 16, further comprising the steps of:

the formation of the base on which to place one of the selected devices: a device for styling hair or an iron when it is not used as a moving device; and

placing at least one electrical connector in the base for attaching an external power source to the heating element to preheat the heating element to the desired operating level before one of the selected devices is used as a moving energy-consuming device.

18. The method of claim 17, further comprising the steps of:

placing additional electrical connectors and introducing additional electronic circuits into the base to provide voltage for charging the internal power source only when energy is supplied to the heating element of one of the selected devices located on the base from the external power source.

19. The method of claim 12, further comprising the steps of:

the formation of the base on which the body of the power-consuming device is placed when it is not used as a moving device; and

the introduction of at least one of the additional electrical connectors associated with the base, for insertion into at least one outlet connected to the housing, for connecting an external power source to one DC heating element for pre-heating the heating element to the desired operating level .

20. The method of claim 4, further comprising the steps of:

using the first spiral wound resistive strip as an AC heating element, and

using a second resistive strip wound in the form of a spiral, alternating with the first wound resistive strip and electrically isolated from it, as a direct current heating element.

21. The method of claim 4, further comprising the steps of:

use of a first planar conductive resistor as an AC heating element, and

applying a second flat conductive resistor to a first flat conductive resistor electrically isolated from it as a direct current heating element.

22. The method of claim 16, further comprising the steps of:

forming part of one of the selected devices: devices for styling hair and iron in the form of a handle, and

placement of the power source inside the handle of the selected device.

23. The method according to p. 22, further comprising the step of introducing a galvanic (battery) element of the rod type into the handle of the selected device <and using it> as an internal power source.

24. The method according to p. 22, further comprising the step of introducing a sequence of many separate galvanic (battery) cells inside the handle of the selected device as an internal power source.

25. The method of claim 1, further comprising the steps of:

the use of galvanic (battery) cells as a power source located inside the case;

providing a latch for holding the housing in a connected state with a power-consuming device;

linking at least one first electrical connector to a latch to connect an external power source to a power-consuming device, to force the power-consuming device to achieve a desired operating level; and

linking at least one second electrical connector to the latch to allow the use of an external DC power source to charge the battery cells located inside only when the power-consuming device is connected to the latch so that when the device reaches the desired operating level, the device could disconnect from the latch, thus disconnecting the external power source from the device and making the device movable by using anija disposed within the battery cells.

26. A method of creating a movable heating device containing the steps:

the formation of the hull with a heating element located inside it;

bringing the heating element to the desired temperature by using the first power source with a fixed location;

disconnecting the heating element from the first power source when the desired temperature is reached to create a movable heating device and

maintaining the desired temperature of the heating element using a second DC power source located inside the movable heating device.

27. A method of operating a movable power-consuming device, comprising the steps of:

preservation of the kinetic energy of the device by using a power source located outside the device;

the simultaneous conservation of electrical energy of a power source located inside the device only during the conservation of the kinetic energy of the device in such a way that when the external power source is separated from the device, an internal source provides electric power to maintain the conservation of kinetic energy; and

cooling and prolonging the life of the internal power source by blowing the external power source with external air only when using the internal power source to maintain the conservation of kinetic energy, thereby maximizing the amount of energy that can be obtained from the power source.

28. The method of claim 14, further comprising the step of: attaching an electronic switch comprising either a field effect transistor or a relay between the power-consuming load and the internal power source to control the energy supplied to the power-consuming load using time-modulated pulse signals.

29. Movable energy-consuming device, containing:

body part with associated energy-consuming load, where there are energy losses in the load system;

a power source located outside the housing and connected, with the possibility of disconnection, to the energy-consuming load associated with the housing, to force the energy-consuming load to achieve the desired operating level; and

a power source located inside the case and connected to the energy-consuming load only after the energy-consuming load reaches the desired operating level and the external power source is separated from it, to compensate for the energy loss in the system and to maintain the desired operating level of the energy-consuming load.

30. The device according to p. 29, further comprising:

at least one heating element connected to the body part as an energy-consuming load to achieve the desired temperature when connected, with the possibility of disconnection, to an external power source;

at least one heating element that is automatically connected to the internal power source only after disconnecting the external power source from the device, where an adequate amount of energy is supplied using the internal power source to maintain the desired temperature achieved by heating with an external power source.

31. The device according to p. 30, in which:

An external power source is an AC power source; but

The internal power source is a DC power source.

32. The device according to p. 31, in which at least one heating element comprises:

an AC heating element, removably connected to an external power source to heat the device to a desired temperature; and

DC heating element for automatic connection to the internal power source to maintain the desired temperature of the device, only after disconnecting the external power source from the AC heating element.

33. The device according to p. 30, in which:

An external power source is a DC power source; and

The internal power supply is also a DC power source.

34. The device according to p. 33, further comprising:

one DC heating element located in the housing;

an externally located AC power source comprising a rectified current output to provide direct current to the output, which is supplied to a single DC heating element to achieve a desired temperature; and

an internal DC power source that is automatically connected to a single DC heating element to provide enough energy to maintain the desired temperature only after disconnecting one DC heating element from the DC output after rectification from an external AC power source.

35. The device according to p. 29, further comprising:

a normally closed electrical switch located between and connected to at least one energy-consuming load and located inside the power source; and

a connector connected to an external power source for automatically opening a normally closed electrical switch when an external power source is connected to at least one power-consuming load to prevent the inside power source from being connected to at least one power-consuming load.

36. The device according to p. 35, in which the connector contains:

an electrical plug for inserting it into an outlet connected to the housing of the power-consuming device, for connecting an external power source to at least one power-consuming load; and

an electric plug, with which, when inserted into the outlet, the electric switch is automatically opened and the connection of the internal power supply to at least one energy-consuming load is prevented.

37. The device according to p. 36, further comprising a direct current circuit for charging, connected to an external power source, for automatically charging an internal power source when an external power source is connected to an energy-consuming load associated with the device.

38. The device according to p. 29, further containing a control circuit connected between the internal power source and the power-consuming load, to automatically maintain the desired operating level only when the device is a relocatable device, to save, thus, located inside the power source, as well as increase energy-consuming load life.

39. The device according to p. 38, further comprising:

a feedback device for generating a signal representing a working load level at a given point in time; and

a control circuit by which a feedback signal is used to reduce the amount of energy supplied to the input of the energy-consuming load from the internal power source to an amount sufficient only to compensate for losses in the system, thereby preserving electrical energy by maintaining the desired operating load level with reduced supply input energy.

40. The device according to p. 39, further comprising:

electronic network switch, represented either by a field-effect transistor, or a relay connected between the power-consuming load and the internal power source; and

a control circuit by which the electronic network switch is switched to the “On” and “Off” positions using time-modulated pulse signals to reduce the input power in such a way as to supply only a sufficient amount of energy to the energy-consuming load to maintain the desired operating level.

41. The device according to p. 29, further comprising:

one of the selected devices: a hair styling device or an iron, which is an energy-consuming device; and

a heating element in one of the selected devices: a hair styling device or an iron used as an energy-consuming load.

42. The device according to p. 41, further comprising:

the basis for the location on it of one of the selected devices: devices for styling hair or an iron, and

at least one electrical connector in the base for connecting an external power source to the heating element for preheating the heating element to the desired operating level before one of the selected devices: a hair styling device or an iron is used as a power-consuming device.

43. The device according to p. 42, additionally containing additional electrical connectors and circuits connected to the base, to provide voltage for charging the internal power source, only when the heating element of the selected device located on the base is supplied with energy from an external power source.

44. The device according to p. 37, further comprising:

a base on which the housing of the power-consuming device is located when it is not used as a moving device; and

at least one electric plug, which forms part of the base, for introducing it into at least one outlet connected to the housing part, for connecting an external power source to one direct current heating element for preheating the heating element to the desired operating level.

45. The device according to p. 32, further comprising:

a first spiral wound resistive strip as an AC heating element; and

a second resistive strip wound in the form of a spiral, alternating with the first wound resistive strip and electrically isolated from it, as a direct current heating element.

46. The device according to p. 32, further comprising:

a first flat resistive conductor as an AC heating element; and

a second flat resistive conductor located on the first flat resistive conductor and electrically isolated from it, as a direct current heating element.

47. The device according to p. 41, further comprising:

a handle that is part of one of the selected devices: devices for styling hair and iron; and

internal power supply located in the handle of the device.

48. The device according to p. 47, in which the internal power source located in the handle of the device contains a galvanic (battery) element of the rod type.

49. The device according to p. 47, in which the internal power source located in the handle of the device contains many separate series-connected galvanic (battery) cells.

50. A movable heating device comprising:

a housing part with a heating element located therein;

an external power source connected, with the possibility of disconnection, to the body part, to bring the heating element to the desired temperature and subsequent disconnection from the body part to form a movable device; and

an internal power source selectively connected to the heating element to maintain the desired temperature of the heating element in the movable device.

51. An improved portable power-consuming device, comprising:

a power source located outside the device to maintain the kinetic energy of the device at the desired level;

an external power source that is disconnected from the device to turn the device into a movable device, after reaching the desired level of stored kinetic energy; and

a power source located inside the device to maintain the desired level of kinetic energy after disconnecting the device from an external power source.

52. The device according to p. 51, in which the kinetic energy is stored in the form of <heat at a given> temperature.

53. The device according to p. 51, in which the kinetic energy is stored in the form of energy of a rotating mass.