JP5859590B2 - Power generator - Google Patents

Description

  The present invention relates to a portable power generator that can be used, for example, as an emergency power source in the event of a power failure or as an outdoor power source.

  Conventionally, as an in-house power generator used as an emergency power source in ordinary homes or office buildings, an electric power generator is known which can obtain electric power at the time of a power failure by rotating a generator using an internal combustion engine, a turbine or the like as a drive source. (For example, see Patent Document 1 or 2).

JP 2012-17706 A JP 2002-152977 A

  By the way, conventional power generators require a space for permanent installation of a generator in a house, etc., and the devices themselves are often large and expensive, and the fuel for the power generators must always be provided. It is not popular for use.

  However, in the event of a power outage, electrical equipment necessary for daily life becomes unusable, and if the power outage lasts for a long time, it will cause considerable inconvenience. Therefore, a power generator that can easily be installed in ordinary homes is desired.

  The present invention has been made in view of the above-mentioned problems, and the object of the present invention is to eliminate the need to permanently install a large generator or a dedicated fuel, and to easily maintain a power generator for ordinary households. Is to provide.

In order to achieve the above object, the present invention provides a power generator main body that can store water therein, a steam turbine that rotates by steam pressure, a generator that generates power by rotating by a steam turbine, and water that is stored inside. A boiler chamber for boiling the steam by heating from the outside and supplying steam to the steam turbine, a condensate chamber for condensing steam discharged from the steam turbine, and a pump for returning the condensed water in the condensate chamber to the boiler chamber The power generator main body is heated from the outside to boil water in the power generator main body, and the steam turbine is rotated by the steam pressure.

As a result, for example, by heating the power generation device main body with a heat source outside the gas stove, when the water in the power generation device main body boils, the steam turbine rotates with the steam pressure and is generated by the generator. However, it can generate electricity if external thermal power such as a gas stove can be used. In this case, the steam discharged from the steam turbine is condensed in the condensate chamber, and the condensed water in the condensate chamber is returned to the boiler chamber by the pump, so that the steam discharged from the steam turbine can be reused.

According to the present invention, power can be generated using an external heat source even in the event of a power failure. For example, when it is always available in a general household, it can be easily used in a kitchen or a cylinder-type gas stove. When there is no storage space, the storage space can be small, and there is no need to always have a dedicated fuel. Moreover, since it can also be used in places without a power source such as a campsite, it can also be used as a power source for outdoor use. In this case, since the steam discharged from the steam turbine can be reused, power can be generated for a long time without replenishing new water.

Front sectional drawing of the electric power generating apparatus which shows the 1st Embodiment of this invention AA line arrow direction sectional view Front sectional drawing of the electric power generating apparatus which shows the 2nd Embodiment of this invention B-B arrow direction sectional view

  FIG. 1 and FIG. 2 show a first embodiment of the present invention, which shows, for example, a power generator used for an emergency power source in a general household.

  This power generation device is used by being mounted on a gas stove 1, and generates power by heating with the gas stove 1.

  The gas stove 1 is a gas stove provided in a kitchen or a portable gas stove that is used with a gas cylinder attached thereto, and is always provided in many general households.

  The power generator according to the present embodiment includes a pan-shaped power generator main body 10 formed so as to be placed on the gas stove 1, a pair of steam turbines 20 rotated by steam pressure, and a pair of power generators rotated by each steam turbine 20. Machine 30.

  The power generation device main body 10 is formed in a bottomed cylindrical shape having an open upper surface, and a boiler chamber 11 is provided at the bottom. The power generation device main body 10 includes a condensate chamber 12 provided above the boiler chamber 11, a heat radiating chamber 13 provided above the condensate chamber 12, and a lid 14 that opens and closes the upper surface of the heat radiating chamber 13. Have.

  The boiler chamber 11 is formed so as to be able to accommodate water, and a water supply port 11a capable of supplying water from the outside is provided on a side surface thereof. Further, a drain port 11b capable of discharging water to the outside is provided on the side surface near the bottom surface of the boiler chamber 11. In this case, the water supply port 11a and the drainage port 11b are formed so that an opening part may be opened and closed with a bolt-shaped stopper, for example.

  The condensate chamber 12 is vertically partitioned from the boiler chamber 11 by a first partition wall 15. The first partition wall 15 includes a recess 15 a for storing condensed water, the boiler chamber 11, and each steam turbine 20. A steam supply port 15b is provided to communicate with one end side. In this case, the recess 15 a is provided in the center of the first partition wall 15. In the condensate chamber 12, a pump 16 that pumps the water in the recess 15a to the boiler chamber 11 is provided. The pump 16 sucks the water in the recess 15a from the inflow pipe 16a and passes through the outflow pipe 16b to the boiler. The liquid is discharged into the chamber 11. In this case, the pump 16 is driven by the electric power of each generator 30. In addition, the condensate chamber 12 is vertically partitioned from the heat radiating chamber 13 by the second partition wall 17, and a large number of fins 17 a are provided on the lower surface of the second partition wall 17 (the surface on the condensate chamber 12 side). Is provided. A large number of fins 12 a are also provided on the inner peripheral surface of the condensate chamber 12.

  The heat radiating chamber 13 is a space surrounded by the power generation device main body 10 and the second partition wall 17, and an upper surface thereof is opened by a lid 14 so as to be opened and closed.

  The lid 14 is detachably attached to the upper surface of the heat radiation chamber 13, and a handle 14 a is provided on the upper surface.

  Each steam turbine 20 is disposed in the condensate chamber 12 and has a known configuration in which the rotating blades 22 are rotated by the steam flowing into one end side of the casing 21 from the steam supply port 15b. In this case, each steam turbine 20 is arranged such that the rotation shaft 22a of the rotary blade 22 extends in the lateral direction. Further, a steam discharge port 21a is provided on the other end side of the casing 21, and the steam after rotating the rotary blade 22 is discharged from the steam discharge port 21a to the condensate chamber 12.

  Each generator 30 is arranged in the condensate chamber 12 and has a well-known configuration that is rotated by the rotating shaft 22 a of the steam turbine 20. In this case, for example, a synchronous generator that generates AC power is used for each generator 30. The generators 30 are coaxially connected to the steam turbines 20, and the steam turbines 20 and the generators 30 are arranged in parallel at intervals in the radial direction of the power generator main body 10. Each generator 30 is connected to a power output socket 31 (plug insertion port) provided on the side surface of the power generation apparatus main body 10 via a cable 32, and the power output socket 31 includes power cables for various electric devices. Plugs (not shown) can be connected.

  When power is generated by the power generator configured as described above, water is accommodated in the boiler chamber 11 of the power generator main body 10, the power generator main body 10 is placed on the gas stove 1, and the power generator main body is heated by the thermal power of the gas stove 1. The bottom of 10 is heated. Next, when the water in the boiler chamber 11 boils, steam flows from the steam supply port 15b of the boiler chamber 11 into one end side of the casing 21 of each steam turbine 20, and each steam turbine 20 and each generator 30 is generated by the steam pressure. Rotates. As a result, the electric power generated by each generator 30 is supplied to the electrical equipment connected to the socket 31. In addition, the steam in each steam turbine 20 is discharged into the condensate chamber 12 from the steam discharge port 21 a after rotating the rotary blade 22, condensed in the condensate chamber 12, and recessed in the condensate chamber 12. Accumulate at 15a. At that time, the steam in the condensate chamber 12 is condensed by exchanging heat with the external air and the air in the heat radiating chamber 13 through the fins 12a and 17a. Further, the condensed water collected in the recess 15 a is returned to the boiler chamber 11 by the pump 16.

  As described above, according to the power generation apparatus of the present embodiment, the water in the power generation apparatus body 10 is boiled by heating the power generation apparatus body 10 from the outside with the gas stove 1, and each steam turbine 20 and each power generation is performed with the steam pressure. Since the machine 30 is rotated to generate power, power can be generated even when a power failure occurs, and the necessary electrical equipment can be used with the generated power.

  In this case, since the power generation device main body 10 is formed in a pan shape that can be placed on the gas stove 1, it can be easily used in a kitchen or a cylinder-type gas stove when it is always used in a general household, and when not in use The storage space can be small, and power can be generated with the heating power of the gas stove 1, so that there is no need to always have a dedicated fuel, and there is an advantage that it is easy to have a regular home. A seven wheel may be used instead of the gas stove 1.

  Moreover, the boiler chamber 11 which boiles the water accommodated in the inside by heating from the outside and supplies steam to each steam turbine 20, the condensate chamber 12 which condenses the steam discharged from each steam turbine 20, and the condensate Since the pump 16 that returns the condensed water in the chamber 12 to the boiler chamber 11 is provided, the steam discharged from each steam turbine 20 can be reused and power can be generated for a long time without replenishing new water. Can do.

  Furthermore, since the heat radiating chamber 13 capable of accommodating an arbitrary object is provided and the heat of the condensing chamber 12 is released into the heat radiating chamber 13, if water is put in the heat radiating chamber 13, Has the advantage that it can be used as a substitute for an electric kettle. In this case, for example, the retort food can be heated with hot water in the heat radiation chamber 13, or the hot water in the heat radiation chamber 13 can be used for cup noodles. Further, any food can be directly put and heated without putting water in the heat radiation chamber 13. Furthermore, when nothing is put in the heat radiating chamber 13, heat removal from the condensate chamber 12 can be promoted by removing the lid 14 and opening the upper surface of the heat radiating chamber 13.

  Further, since each steam turbine 20 is arranged so that the rotating shaft 22a extends in the lateral direction of the power generation apparatus main body 10, the vertical dimension of the power generation apparatus main body 10 can be reduced, which is extremely advantageous for downsizing.

  3 and 4 show a second embodiment of the present invention, and the same reference numerals are given to the same components as those in the previous embodiment.

  The power generator according to this embodiment includes a pan-shaped power generator main body 40 formed so as to be placed on the gas stove 1, a steam turbine 50 that rotates by steam pressure, and a generator 60 that rotates by the steam turbine 50. Yes.

  The power generator main body 40 is formed in a bottomed cylindrical shape having an open top surface, and a boiler chamber 41 is provided at the bottom. The power generator main body 40 includes a turbine chamber 42 provided above the boiler chamber 41, a condensate chamber 43 provided above the turbine chamber 42, and a heat radiating chamber 44 provided above the condensate chamber 43. And a lid 45 that opens and closes the upper surface of the heat radiating chamber 44.

  The boiler chamber 41 is formed so as to be able to accommodate water, and a water supply port 41a capable of supplying water from the outside is provided on a side surface thereof. Further, a drain port 41b capable of discharging water to the outside is provided on a side surface near the bottom surface of the boiler chamber 41. In this case, the water supply port 41a and the drainage port 41b are formed so that an opening part may be opened and closed with a bolt-shaped stopper, for example.

  The turbine chamber 42 is vertically partitioned from the boiler chamber 41 by a first partition wall 46, and the first partition wall 46 has a plurality of steams communicating with the inside of the boiler chamber 41 and the upper surface side of the steam turbine 50. A supply port 46a is provided.

  The condensate chamber 43 is partitioned vertically from the boiler chamber 41 by a second partition wall 47. The second partition wall 47 includes a recess 47 a for storing condensed water, the inside of the condensate chamber 43, and the steam turbine 50. A plurality of steam discharge ports 47b that communicate with the lower end side of the gas is provided. In this case, the recess 47 a is provided on the periphery of the second partition wall 47. In the condensate chamber 43, there is provided a pump 48 for pumping water in the recess 47a to the boiler chamber 41. The pump 48 sucks water in the recess 47a from the inflow pipe 48a and passes through the outflow pipe 48b to the boiler. The liquid is discharged into the chamber 41. In this case, the pump 48 is driven by the electric power of the generator 60. The condensate chamber 43 is partitioned from the heat radiating chamber 44 vertically by a third partition wall 49, and a large number of fins 49 a are provided on the lower surface of the third partition wall 49 (the surface on the condensate chamber 43 side). Is provided. A large number of fins 43 a are also provided on the inner peripheral surface of the condensate chamber 43.

  The heat radiating chamber 44 is a space surrounded by the power generation device main body 40 and the third partition wall 49, and its upper surface is opened by a lid 45 so as to be opened and closed.

  The lid 45 is detachably attached to the upper surface of the heat radiation chamber 44, and a handle 45a is provided on the upper surface.

  The steam turbine 50 is arranged in the turbine chamber 42 and has a known configuration in which the rotating blades 52 are rotated by the steam that flows into the lower surface side of the casing 51 from each steam supply port 46a. In this case, the steam turbine 50 is disposed such that the rotation shaft 52 a of the rotary blade 52 extends in the vertical direction, and the rotation shaft 52 a is disposed at the center of the power generator main body 40. Further, the upper surface side of the casing 51 communicates with the steam discharge port 47 b of the second partition wall 47 so that the steam after rotating the rotary blade 52 is discharged from the steam discharge port 47 b to the condensate chamber 43. It has become.

  The generator 60 is disposed in the condensate chamber 43 and has a known configuration that is rotated by the rotation shaft 52 a of the steam turbine 50. In this case, the generator 60 is, for example, a synchronous generator that generates AC power. The generator 60 is coaxially connected to the steam turbine 50, and the steam turbine 50 and the generator 60 are arranged one above the other with the second partition wall 47 therebetween. The generator 60 is connected to a power output socket 61 (plug insertion port) provided on the side surface of the power generator main body 40 via a cable 62, and the power output socket 61 includes power cables for various electric devices. An insertion plug (not shown) can be connected.

  When power is generated by the power generator configured as described above, water is stored in the boiler chamber 41 of the power generator main body 40 and the power generator main body 40 is placed on the gas stove 1 as in the first embodiment. The bottom of the power generation device main body 40 is heated by the heating power of the gas stove 1. Next, when the water in the boiler chamber 41 boils, steam flows from the steam supply ports 46b of the boiler chamber 41 to the lower surface side of the casing 51 of the steam turbine 50, and the steam turbine 50 and the generator 60 are rotated by the steam pressure. To do. Thereby, the electric power generated by the generator 60 is supplied to the electrical equipment connected to the socket 61. Further, the steam in the steam turbine 50 is discharged into the condensate chamber 43 from the steam discharge port 47 b after rotating the rotary blade 52, condensed in the condensate chamber 43, and a recess 47 a in the condensate chamber 43. Accumulate. At that time, the steam in the condensate chamber 43 is condensed by exchanging heat with the external air and the air in the heat radiating chamber 44 through the fins 43a and 49a. The condensed water collected in the recess 47 a is returned to the boiler chamber 41 by the pump 48. In the steam turbine 50, the steam that has flowed into the casing 51 from each steam supply port 46b is discharged from the steam discharge ports 47b adjacent to each other in the rotation direction of the rotary blade 52 among the plurality of steam discharge ports 47b. .

  Thus, according to the power generator of this embodiment, the water in the power generator main body 40 is boiled by heating the power generator main body 40 from the outside with the gas stove 1, and the steam turbine 50 and the generator 60 are heated by the vapor pressure. As in the first embodiment, power can be generated if the power of the gas stove 1 can be used even during a power failure, and necessary electrical equipment can be used with the generated power.

  Further, since the steam turbine 50 is arranged so that the rotary shaft 52a extends in the longitudinal direction of the power generator main body 40, the rotary blade 52 can be enlarged in the radial direction of the power generator main body 40, and the output of the steam turbine 50 is increased. be able to. In this case, the steam that has flowed into the casing 51 of the steam turbine 50 from the plurality of steam supply ports 46b is discharged from the steam discharge ports 47b adjacent to each other in the rotation direction of the rotary blades 52 among the plurality of steam discharge ports 47b. As a result, the efficiency of the steam turbine 50 can be increased. Other effects are the same as those of the first embodiment.

  Further, in each of the first and second embodiments, the power generator main bodies 10 and 40 are formed in a pan shape that can be placed on the gas stove 1. It is not limited to.

  In each of the first and second embodiments, the case where the power generator is used in a general household at the time of a power failure has been shown. However, the power generation device is easy to carry, and therefore, in a place where there is no power source such as a campsite. It can also be used as a power source for outdoor use.

  Further, in each of the first and second embodiments, the power generator main bodies 10 and 40 are formed in a pan shape that can be placed on the gas stove 1. It is not limited to.

  DESCRIPTION OF SYMBOLS 10 ... Power generator main body, 11 ... Boiler room, 12 ... Condensate room, 13 ... Radiation room, 16 ... Pump, 20 ... Steam turbine, 30 ... Generator, 40 ... Power generator main body, 41 ... Boiler room, 42 ... Recovery Water chamber, 43 ... radiation chamber, 46 ... pump, 50 ... steam turbine, 60 ... generator.

Claims (5)

A power generator body capable of containing water inside,
A steam turbine rotating by steam pressure;
A generator for generating electricity by rotating by a steam turbine ;
A boiler chamber for boiling water contained in the interior by heating from the outside and supplying steam to the steam turbine;
A condensate chamber for condensing the steam discharged from the steam turbine;
A pump that returns the condensed water in the condensate chamber to the boiler chamber ,
A power generator configured to boil water in a power generator main body by heating the power generator main body from the outside, and to rotate a steam turbine with the steam pressure. The power generator according to claim 1, wherein the power generator main body is formed in a pan shape that can be placed on a gas stove. The power generator according to claim 1 or 2 , further comprising: a heat dissipating chamber that is formed so as to be capable of accommodating an arbitrary object and in which heat of the condensate chamber is released. The power generator according to claim 1, 2, or 3, wherein the steam turbine is arranged such that a rotating shaft extends in a lateral direction of the power generator main body. The power generator according to claim 1, 2, or 3, wherein the steam turbine is arranged such that a rotating shaft extends in a longitudinal direction of the power generator main body.

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