KR102095737B1 - Gadolinium Heat conversion Generator with Scalability - Google Patents

Abstract

The present invention relates to a gadolinium heat conversion generator with scalability. Accordingly, a technical subject of the present invention is to allow the gadolinium heat conversion generator with scalability to be formed to be able to variably expand and adjust the number of stages of a circular rotor having a gadolinium block to a plurality of stages or a selected arbitrary stage so as to obtain high torque compared to the same energy input, thereby enabling high output power production. Moreover, the gadolinium heat conversion generator with scalability is formed so that a drive gear ratio of a gadolinium rotor can be easily adjusted as necessary (including the driven gear ratio associated with the same) to significantly improve connectivity with a subsequent generator (or a subsequent processing device) so as to improve excellent variability, productivity and usability compared to the past.

Description

Gadolinium heat conversion generator with scalability

The present invention enables the variable rotation and expansion of the circular rotor provided with a gadolinium block to a plurality of stages or any selected stage, so that a high torque compared to the same energy input can be obtained, which enables high output power production. Of course, the gear ratio of the gadolinium rotor can be easily and precisely adjusted as necessary (including the driven gear ratio associated therewith), so that the linkage with the subsequent generator (or subsequent processing device) is significantly improved, which greatly improves the usability. It is characterized by a scalable gadolinium heat conversion generator.

The prior patent registration No. 10-1940145 (2019.01.14.) Is a prior document registered and registered by the applicant of the present application, and relates to a gadolinium low temperature difference generator in connection with a cylinder type rotary friction electric system.

Such prior literature is that a plurality of gadolinium blocks are provided in a circular rotor, and when a low temperature difference due to cold water and hot water supply occurs, weak and ferromagnetic properties are repeated, causing a one-side rotation induction magnet to rotate the circular rotor in the circumferential direction to generate electricity. It is formed to be the basis.

On the other hand, in the gadolinium heat conversion generator of the prior art, as shown in FIG. 11, the circular rotor of the gadolinium rotor is fixed at one stage, thereby greatly widening the temperature difference of the energy source (hot or cold water) in order to generate higher torque. Or increase the flow rate.

However, in the prior art, alternatives for promoting the expansion of the temperature difference, which is an energy source, or for increasing the flow rate have to increase the energy input, which causes a problem that energy efficiency is rather reduced. In particular, the circular rotor in the existing literature is a magnet. Due to the coupling structure of the holder, interference is generated, and it is almost impossible to adjust the gear ratio or expand the size, thus limiting the high torque output.

1. Republic of Korea Registered Patent No. 10-1940145 (2019.01.14.)

The present invention is to solve the above-mentioned problems, the technical gist of which is formed so as to be able to variably expand and adjust the number of stages of a circular rotor equipped with a gadolinium block to a plurality of stages or to any stage selected, a significantly higher torque compared to the same energy input The purpose of this is to provide a high output power generation possible.

In addition, the present invention is formed so that the drive gear ratio of the gadolinium rotor can be easily adjusted as necessary (including driven gear ratios associated therewith), thereby significantly improving the linkage with subsequent generators (or subsequent processing devices), which is superior to the previous The aim is to provide an improvement in variability, productivity and usability.

In other words, the present invention is easy to secure an eco-friendly energy resource and can secure various utilizations, and uses a characteristic of gadolinium (Gd) to utilize a low-temperature waste heat source as an energy source, which is an energy supply source. The purpose is to provide something that can enhance the diversification of the company.

In order to achieve this object, the present invention allows one or more of the plurality of circular rotors 120 along the longitudinal direction of the rotor shaft 110 to be assembled into a detachable variable structure through the central coupling hole 121, but the circular rotor A plurality of gadolinium blocks 130 are formed to be assembled on the circumferential surface of 120, and the gadolinium blocks 130 are weakly formed by cold water and hot water sprayed at a set position on the circumferential surface of the circular rotor 120, respectively. When the ferromagnetic is repeatedly generated, the one-side rotation induction magnet 140 is formed to rotate the circular rotor 120 in the circumferential direction, and gadolinium allows the driving gear 150 to be coupled to one end of the rotor shaft 110. A rotor 100; A power transmission unit that is coupled to a driven gear 220 at one end of the driven shaft 210 so as to correspond to the drive gear 150 of the rotor shaft to transmit a power source generated from the gadolinium rotor 100 to a subsequent generator or processing device ( 200) and; A support bracket 320 and a variable bracket 330 that can be moved along the lane 311 formed on the upper surface of the table 310 are provided, respectively, but the support bracket 320 includes a standing plate 321 and a connecting plate ( 322) is formed to form a '∩'-type structure, the standing plate 321 is formed such that the bearing rotor 323 is formed on one side of the surface so that the mounted rotor shaft 110 can rotate, and the connection The upper surface of the plate 322 and the surface of the table 310, one side and the other side are formed so that the cold water supply pipe 340 and the hot water supply pipe 350 having a water supply hole 341,351 and a drain hole 342,352 are fixed and seated, and the variable bracket ( 330 is formed on one side adjacent to the support bracket 320 to be able to adjust the position relative to the support bracket 320 along a plurality of lanes 311, wherein the variable bracket 330 includes a plurality of transfer plates ( 331) is formed so that the distance control plate 332 is assembled in the direction orthogonal to the upper side, One side of the plane of the transfer plate 331 is provided with a bearing 333 is provided with a variable adjustment unit 300 to allow the driven shaft 210 to rotate; It consists and is made.

Thus, the hot water sprayed to the circular rotor 120 in which the gadolinium block 130 is assembled is formed to flow downward from one side of the upper portion of the radius of the circumferential surface of the circular rotor 120, and cold water is circular ash It is sprayed so as to ascend upward from one side of the circumferential surface of the former 120 so that the contact surfaces of cold water and hot water are distributed over the entire surface of each radius.

At this time, the distance control plate 332 is such that a plurality of assembly holes 334 are arranged at equal intervals in one direction on the upper surface, but a fastening hole 335 is formed on the upper surface of the transfer plate 331 corresponding to the assembly hole 334 It is formed so that the fixed position can be changed when the length of the driven shaft 210 is changed or the distance from the subsequent generator or processing device is adjusted.

As described above, the present invention is formed so as to be able to variably expand and adjust a circular rotor equipped with a gadolinium block to a plurality of stages or to any selected stage, so as to obtain a high torque compared to the same energy input. Not only is it possible, but the gear ratio of the gadolinium rotor can be easily and precisely adjusted as necessary (including the driven gear ratio associated with it), which significantly improves the usability by significantly improving the linkage with the subsequent generator (or subsequent processing device) It is effective.

That is, the present invention is easy to secure eco-friendly energy resources, and can secure various versatility. When the characteristics of gadolinium (Gd) are low (when the temperature is low (below about 20 ° C), it shows strong magnetism, and when the temperature is high ( (About 30 ℃ or higher), so that it can utilize a low-temperature waste heat source as an energy source by using a weak magnet], which aims to provide a means to improve diversification of energy sources.

1 is an exemplary use state diagram of a gadolinium heat conversion generator with expandability according to the present invention,
Figure 2 is a side view showing the gadolinium rotor of Figure 1,
Figure 3 is an exemplary view showing that the hot and cold water supply port is applied to the gadolinium rotor according to the present invention,
Figure 4 is an exemplary view showing that the drive gear and the driven gear can be variably applied to the gadolinium rotor and the power transmission unit according to the present invention,
Figure 5 is an exemplary view showing a table with a lane according to the invention,
Figure 6 is an exemplary view showing a standing plate according to the present invention,
7 is an exemplary view showing a connecting plate according to the present invention,
8 is an exemplary view showing a transfer plate according to the present invention,
9 is an exemplary view showing a distance control plate according to the present invention,
10 is an exemplary view showing a side type and an intermediate connection type of a circular rotor according to the present invention;
11 is an exemplary view showing a prior art document.

Next, the present invention will be described in more detail with reference to the accompanying drawings.

First, as shown in FIGS. 1 to 10, the present invention is largely composed of a gadolinium rotor 100, a power transmission unit 200, and a variable adjustment unit 300.

Thus, the gadolinium rotor 100 is formed such that one or more of the plurality of circular rotors 120 along the longitudinal direction of the rotor shaft 110 is assembled into a detachable variable structure through the central coupling hole 121.

At this time, a plurality of gadolinium blocks 130 are formed on the circumferential surface of the circular rotor 120.

Thus, the hot water sprayed to the circular rotor 120 in which the gadolinium block 130 is assembled is formed to flow downward from one side of the upper portion of the radius of the circumferential surface of the circular rotor 120, and cold water is circular ash It is sprayed so as to ascend upward from one side of the circumferential surface of the former 120 so that the contact surfaces of cold water and hot water are distributed over the entire surface of each radius.

At this time, the circular rotor 120 is formed with a mounting groove 122 so that a plurality of fixed shafts 160 are inserted on the surface, thereby intermittently preventing multiple circular rotors from rotating individually.

In addition, the circular rotor is provided with auxiliary fixing pins 190 and fixing grooves 180 to prevent temporary assembly and rotation with adjacent aides.

In more detail, the gadolinium block is a cold water supply pipe 340 and a hot water supply pipe having water supply holes 341 and 351 and drain holes 342 and 352 on one side and the other side of the upper surface of the connecting plate 322 and the table 310, which will be described later. Cold water and hot water at a temperature set by 350 flow directly in contact with the surface.

At this time, the hot water supply pipe is disposed on the upper surface of the connecting plate, and the cold water supply pipe is provided on one side and the other side of the table, respectively.

Accordingly, the cold and hot water supply pipes are formed such that cold water and hot water are respectively supplied to them, and flexible drainage pipes are connected to a plurality of drainage holes communicated in a direction orthogonal to the water supply holes, so that the desired upper and lower sides of the circular rotor are desired. It is formed to be able to position the water supply end in position.

In other words, hot water sprayed to the circular rotor 120 in which the gadolinium block 130 is assembled is formed to flow downward from one side of the upper portion of the radius of the circumferential surface of the circular rotor 120, and cold water is circular It is sprayed so as to rise upward from one side of the lower circumference of the circumferential surface of the rotor 120 so that the contact surfaces of cold water and hot water are distributed over the entire surface of each radius.

This is to ensure that the rotation performance is enhanced due to the expansion of the thermal distribution of cold water or hot water.

The gadolinium block is formed such that the circular rotor 120 rotates in the circumferential direction while the one-side rotation induction magnet 150 is repeated while the weak and ferromagnetic properties are repeated due to the variable temperature difference between the hot and cold water.

For reference, a water drainage groove 170 is formed on the top surface of the table where the gadolinium rotor is disposed to be drained to a separate drain line (not shown).

On the other hand, the gadolinium block is formed to be bolted when coupled to a circular rotor, so that it can be easily detached when the size is changed.

At this time, the gadolinium block is a block having a width * length * height of about 1cm * 1cm * 1cm, for example, and a fastening groove is formed on the lower side, and the fastening groove corresponds to a planar coupling hole of a coupling ring formed on the outer circumferential surface of the circular rotor As it is, it is formed to be screwed by a mood bolt or countersunk bolt or a small piece.

Accordingly, it is preferable that a seat groove is formed on the surface of the coupling ring of the circular rotor so that each gadolinium block can be seated and supported so that flow is prevented.

On the other hand, the rotating induction magnet is disposed on the upper side of the rotor shaft in which the circular rotor is continuously assembled, thereby allowing cold water and hot water to rotate in the direction to be attached to each other by the rotating induction magnet, or to fall in reverse, gadolinium. It is formed to continuously induce circumferential rotation of the transducer.

Incidentally, the gadolinium block causes hot water (G2: about 40 ° C or higher) to turn and spray cold water (G1: about 20 ° C or lower) on one side to rotate, but, if necessary, a second side on the opposite side of the hot water supply channel. A cold water supply path (hour water at about 23 ° C.) is formed to pre-cool the high temperature characteristics to improve the temperature reduction efficiency of the cold water supply path, which is a low temperature section.

That is, the second cold water supply path is a section for pre-cooling for quick magnetic return to the gadolinium block, which is magnetically released by high temperature characteristics, and is about the temperature of normal tap water before entering the cold water passage (about 5 ° C). It is preferable to let the water at 23 ° C flow.

Accordingly, the gadolinium block 130 is weakly and ferromagnetically generated by cold water and hot water sprayed at a predetermined position on the circumferential surface of the circular rotor 120, thereby causing the one-side rotation induction magnet 140 to be a circular rotor. 120 is formed to rotate in the circumferential direction.

At this time, a drive gear 150 is formed at one end of the rotor shaft 110. Such a drive gear can be easily and easily changed when a gear ratio change request is made, and is formed to be linked with a driven shaft driven gear described later.

On the other hand, the power transmission unit 200 is a driven gear 220 is coupled to one end of the driven shaft 210 so as to correspond to the drive gear 150 of the rotor shaft is a subsequent generator or a power source generated from the gadolinium rotor 100 It is formed for delivery to a processing device.

Thus, the variable adjustment unit 300 is formed to be provided with a support bracket 320 and a variable bracket 330, respectively, which can be moved along the lane 311 formed on the upper surface of the table 310.

At this time, the support bracket 320 is formed so that the standing plate 321 and the connecting plate 322 form a '∩' type, and the standing plate 321 is formed with bearing bearings 323 respectively on one side of the surface. The mounted rotor shaft 110 is formed to rotate.

In addition, cold water supply pipes 340 and hot water supply pipes 350 having water supply holes 341 and 351 and drain holes 342 and 352 are formed to be fixed on one side and the other side of the upper surface of the connection plate 322 and the surface of the table 310.

Thus, the variable bracket 330 is formed on one side adjacent to the support bracket 320 and is formed to be able to adjust the position based on the support bracket 320 along a plurality of lanes 311.

At this time, the variable bracket 330 is formed such that the distance adjusting plate 332 is assembled in a direction orthogonal to the upper side of the plurality of transfer plates 331, and a bearing 333 is provided on one side of the plane of the transfer plate 331 The mounted driven shaft 210 is formed to rotate.

Thus, the distance adjusting plate 332 is to be arranged so that a plurality of assembly holes 334 are equally spaced in one direction on the upper surface, the fastening hole 335 is formed on the upper surface of the transfer plate 331 corresponding to the assembly hole 334 It is formed so that the fixed position can be changed when the length of the driven shaft 210 is changed or the distance from the subsequent generator or processing device is adjusted.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be carried out by anyone who has ordinary skill in the art to which the subject design pertains without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

100 ... gadolinium rotor 110 ... rotor shaft
120 ... round rotor 121 ... joiner
130 ... gadolinium block 140 ... rotating induction magnet
150 ... drive gear 200 ... power transmission
210 ... driven shaft 220 ... driven gear
300 ... variable adjustment 310 ... table
311 ... Lane 320 ... Support bracket
321 ... standing plate 322 ... connecting plate
323 ... bearing rotating body 330 ... variable bracket
331 ... Transfer plate 332 ... Distance control plate
333 ... Bearing 334 ... Assembler
335 ... fastener 340 ... cold water supply pipe
341 ... water supply 342 ... water drain
350 ... hot water supply pipe 351 ... water supply
352 ... drainer

Claims (3)

One or more of the plurality of circular rotors 120 along the longitudinal direction of the rotor shaft 110 is to be assembled into a detachable variable structure through the central coupling hole 121, but a plurality of circumferential surfaces of the circular rotor 120 The gadolinium block 130 is formed to be assembled, and the gadolinium block 130 is repeatedly rotated to one side as weak and ferromagnetic properties are repeatedly generated by cold water and hot water sprayed at a set position on the circumferential surface of the circular rotor 120, respectively. A gadolinium rotor 100 configured to cause the magnet 140 to rotate in a circumferential direction, and a driving gear 150 coupled to one end of the rotor shaft 110;
A power transmission unit that is coupled to a driven gear 220 at one end of the driven shaft 210 so as to correspond to the drive gear 150 of the rotor shaft to transmit a power source generated from the gadolinium rotor 100 to a subsequent generator or processing device ( 200) and;
A support bracket 320 and a variable bracket 330 that can be moved along the lane 311 formed on the upper surface of the table 310 are provided, respectively, but the support bracket 320 includes a standing plate 321 and a connecting plate ( 322) is formed to form a '∩'-type structure, the standing plate 321 is formed such that the bearing rotor 323 is formed on one side of the surface so that the mounted rotor shaft 110 can rotate, and the connection The cold water supply pipe 340 and the hot water supply pipe 350 having a water supply hole 341,351 and a drainage hole 342,352 are formed to be fixed on one side and the other side of the upper surface of the plate 322 and the table 310, and the variable bracket ( 330 is formed on one side adjacent to the support bracket 320 to enable position adjustment based on the support bracket 320 along a plurality of lanes 311, wherein the variable bracket 330 includes a plurality of transfer plates ( 331) is formed so that the distance control plate 332 is assembled in the direction orthogonal to the upper side, One side of the plane of the transfer plate 331 is provided with a bearing 333 is a variable adjustment unit 300 to allow the mounted driven shaft 210 to rotate;
Gadolinium heat conversion generator with scalability, characterized by being constructed. According to claim 1, The gadolinium block 130, the hot water sprayed to the assembled circular rotor 120 is formed to flow downward from one side of the upper portion of the circumferential surface radius of the circular rotor 120, Cold water is sprayed to rise upward from one side of the lower circumference of the circumferential surface of the circular rotor 120. Gadolinium heat conversion with expandability characterized in that the cold water and hot water contact surfaces can be distributed over the entire surface of each radius. generator. According to claim 1, The distance control plate 332 is to be arranged so that a plurality of assembly holes 334 are equally spaced in one direction on the upper surface, the fastening hole (335) on the upper surface of the transfer plate 331 corresponding to the assembly hole (334) ) Is formed, the gadolinium heat conversion generator with expandability characterized in that the fixed position can be varied when the length of the driven shaft 210 is changed or the distance to the subsequent generator or processing device is adjusted.

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