MULTI-DRILL CULTI-ROTAVATOR

Abstract

The Multi-drill culti rotavator, according to the present invention, is used for cultivating or ploughing the soil and at the same 10 time, for rotavating the soil for agricultural and gardening purpose. Said culti rotavator effectively drills and cultivates the soil preparing it for the irrigation retaining soil moisture increasing soil absorption capacity of the soil. Said multi drill culti rotavator is hung at the rear end of the tractor. It comprises of: Differential Gear Box Assembly 2, Main Body Assembly 3, Bottom differential Gear box Assembly 4, Gear Axle Assembly 5, End Bearing Housing Assembly 6, Drill Bit Shaft Assembly 7.

Claims

1. An efficient multi drill culti rotavator cultivating and rotavating the soil in single pass, wherein said multi drill culti rotavator P comprises: A Differential Gear Box Assembly 2, A Main Body Assembly 3, A Bottom differential Gear box Assembly 4, A Gear Axle Assembly 5, An End Bearing Housing Assembly 6, A Drill Bit Shaft Assembly 7; Wherein Said Differential Gear Box Assembly 2 facilitating the plurality of gears is connected to the main body Assembly 3; said main body Assembly 3 is pentagonal and is attached to the Differential Gear Box Assembly 2 on one side and to Bottom differential Gear box Assembly 4 on the other; said main body Assembly 3, holds the differential gear box assembly 4; said Bottom differential Gear box Assembly 4 connected to the Gear Axle Assembly 5 on either sides is configured to control the motion of gears; said Gear Axle Assembly 5 consisting plurality of spiral gears, is connected to the Bottom differential Gear box Assembly 4 to transmit the power from Gear Axle Assembly 5 to End Bearing housing Assembly 6; said End Bearing housing Assembly 6 is attached to main body assembly 3; said Drill bit shaft Assembly 7 is the main assembly configured to transmit the power from spiral bevel gears to drill bit 7.2 in clockwise and anticlockwise direction attached to said Bottom differential Gear box Assembly 4.

2. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said Differential Gear Box Assembly 2 comprises: A Gear Box 2.1, A Spur Gear for Primary Shaft 2.2, A Spur Gear for Secondary Transmission Shaft 2.3, A Primary Input Shaft 2.4, A Secondary Transmission Shaft 2.5, A Bearing Cover for Primary shaft & Secondary Shaft 2.6, A Straight Bevel for Secondary Transmission shaft 2.7 A Straight Bevel for Tertiary shaft 2.8 A Bearing Housing for tertiary shaft 2.9 A Tertiary Shaft 2.10, A Straight Bevel for Differential Gear Box 2.11; Said gear box 2.1 houses the plurality of gears and is connected to Bearing Cover for Primary shaft & Secondary Shaft 2.6 on one side and to Primary Input Shaft 2.4 and Secondary Transmission Shaft 2.5, at the other; Said primary input shaft 2.4 is configured to take the input power from the power take off shaft of the tractor and connected to the power take off shaft of the tractor on one side and to Bearing Cover for Primary shaft & Secondary Shaft 2.6 on the other side; said Secondary Transmission Shaft 2.5 is connected to the Straight Bevel for Secondary Transmission shaft 2.7 and is configured for power transmission; Said Spur Gear for Secondary Transmission Shaft 2.3 is connected to the Bearing Cover for Primary shaft & Secondary Shaft 2.6; the input power from the Primary Input Shaft 2.4 and Secondary Transmission Shaft 2.5 is transmitted further to said Spur Gear for Primary Shaft 2.2 and Spur Gear for Secondary Transmission Shaft 2.3; Said Spur Gear for Primary Shaft 2.2, is connected to the Bearing Cover for Primary shaft & Secondary Shaft 2.6; Said Bearing Housing for tertiary shaft 2.9 holds Straight Bevel for Tertiary shaft 2.8 and is connected to Tertiary Shaft 2.10 on the other end; Said Tertiary Shaft 2.10 is connected to the Straight Bevel for Differential Gear Box 2.11 on the other end.

3. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said main body Assembly 3 comprises A Front Cover Plate 3.1, A Top Cover plate 3.2, A Side cover support plate 3.3, A Front Support square pipe 3.4, A Bracket Plate 3.5, A Bracket cover plate 3.6, A Main gear box mounting flat Bar 3.7 A Protector 3.8, The Lifting Arms 3.9, A Differential gear box fixing plate 3.10; Wherein said Front Cover Plate 3.1, Top Cover plate 3.2, Side cover support plate 3.3 and Front Support square pipe 3.4 covers the Bottom differential Gear box Assembly 4; Said bracket cover plate 3.6 attached to Front Support square pipe 3.4 is configured to cover Bracket plate 3.5; Said Bracket plate 3.5 is configured to fix the gears on the back side of tractor; Said Gear box 2.1 mounted over the Main gear box mounting flat Bar 3.7; protector 3.8 at the either edges of the main body Assembly 3 protects the main body Assembly 3; Said Lifting Arms 3.9 connected to the Front Support square pipe 3.4 are provided to lift present invention; said Differential gear box fixing plate 3.10 is connected to the bottom differential gar box assembly 4.

4. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said Bottom differential Gear box Assembly 4 comprises: A Differential Gear Box bearing housing 4.1, A Straight Bevel for Differential Gear Box 4.2, An Axle for Differential Gear Box 4.3, A Differential Gear Box Plate 4.4; Wherein said Differential Gear Box bearing housing 4.1 houses Axle for Differential Gear Box 4.3 and Differential Gear Box Plate 4.4 on either sides; said Differential Gear Box 4.3 is configured to transmit the power from Straight Bevel for Differential Gear Box 4.2 to Gear Axle Assembly 5; Said Differential gear box plate 4.4 connected to the Straight Bevel for Differential Gear Box 4.2 and is attached to said gear box 2.1; Said Axle for Differential Gear Box 4.3 connects Gear Axle Assembly 5 on both side.

5. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said Gear Axle Assembly 5 comprises; An Axle 5.1, A Flange for Axle 5.2, A Main spiral Bevel Gear 5.3, A Collar for Main Gear 5.4, A Collar for middle main gear 5.5 Wherein said Axle 5.1 connected to the flange for axle 5.2 supporting axle 5.1 on one end and to the collar for main gear 5.4 on the other end is configured to rotate spiral gears; Said collar for main gear 5.4 houses plurality of Main spiral Bevel Gear 5.3 configured to translate the force from one direction to another direction enabling rotation of shafts in clockwise and anticlockwise directions.

6. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 5 wherein said Main spiral Bevel Gear 5.3 are in pair of six gears.

7. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said End Bearing housing Assembly 6 comprises An End Bearing Housing 6.1, An Axle for End Bearing Housing 6.2, An End Bearing Housing Cover 6.3; Wherein said End Bearing Housing 6.1 is connected to end bearing housing cover 6.3; Said Axle for End Bearing Housing 6.2 is housed in the end bearing housing 6.1 and is configured to connect with Gear Axle Assembly 5.

8. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 1, wherein said Drill bit shaft Assembly 7 comprises; Drill bit Shaft 7.1, Drill bits 7.2, Drill Bit Bearing Housing 7.3, Spiral bevel gear 7.4; Wherein said Drill bit Shaft 7.1 is configured to connect the drill bit bearing housing 7.3 and spiral bevel gear 7.4, transfer the input power to said drill bits 7.2; Said spiral bevel gear 7.4 are in plurality and are in connection with corresponding Main spiral Bevel Gear 5.3 configured to provide motion to present invention; Said spiral bevel gears 7.4 are connected to the plurality of drill bits 7.2 connected to the corresponding rotavation blades; Wherein each drill bit 7.2 comprises ploughing section with plurality of rotavator blades curved on flat on the upper most edge of the drill bit 7.2 at 120° with outward convexity; Said blades are fixed perpendicularly to the drill bits configured to initiate rotation in reverse direction than that of the adjoining drill bit; drilling multiple furrows at a time.

9. The multi drill culti rotavator cultivating and rotavating the soil in single pass, as claimed in claim 8, wherein said spiral bevel gear 7.4 are six in pair, said drill bits 7.2 are twelve and said rotavator blades are three rotavator blades for each twelve drill bits 7.2.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0035]

TABLE-US-00001 FIG. 1A: Shows the front view of present multi drill culti rotavator P FIG. 1B: Shows the back view of present invention P FIG. 2: Shows the fragmented view of Differential Gear Box Assembly 2 of the present Invention P. FIG. 3: Shows the Fragmented view of Main Body Assembly 3 of the present Invention P. FIG. 4: Shows the Fragmented view of bottom differential Gear box Assembly 4 of the present invention P. FIG. 5: Shows the Fragmented view of Gear Axle Assembly 5 of the present invention P. FIG. 6A: Shows the Fragmented View of End Bearing Housing Assembly 6A of the present invention P. FIG. 6B: Shows the Fragmented View of Drill Bit Shaft Assembly 6B of the present invention P.

SUMMARY OF THE PRESENT INVENTION

[0036] In order to achieve the foregoing objects the present invention provides multi drill culti-rotavator that prepares seed bed with substantially improved tilth in single pass. Said culti rotavator effectively drills and cultivates the soil preparing it for the irrigation retaining soil moisture increasing soil absorption capacity of the soil. Said multi drill culti rotavator is hung at the rear end of the tractor. It comprises of: [0037] Differential Gear Box Assembly 2, [0038] Main Body Assembly 3, [0039] Bottom differential Gear box Assembly 4, [0040] Gear Axle Assembly 5, [0041] End Bearing Housing Assembly 6, [0042] Drill Bit Shaft Assembly 7.

[0043] It facilitates producing multifold work at a time. Wherein the drilling process, dropping the seeds in furrows in a continuous flow and then covering them with soil.

[0044] Moreover the rotavator blades of the present invention, enables the transfer impact on soil surface throwing the soil upward due to its rotating speed. It facilitates breaking of big chunks of soil and making it ready for any plantation or seeding at the same time, that to in a single pass instead of multiple passes for cultivation.

DETAILED DESCRIPTION OF INVENTION

[0045] An embodiment of the present invention provides a multi drill culti rotavator P for cultivating or ploughing the soil and at the same time, for rotavating the soil for agricultural and gardening purpose. Said multi drill Culti-rotavator is energy efficient, user friendly, ecofriendly as well as saves substantial time. The present invention cultivates as well as rotavates the soil in a single pass utilizing minimum tractor fuel and provides maximum output.

MEANING OF REFERENCE NUMERALS USED IN THE PRESENT MULTI DRILL CULTI ROTAVATOR P

[0046] P: Present Multi Drill Culti-Rotavator [0047] 2: Differential Gear Box Assembly [0048] 3: Main Body Assembly [0049] 4: Bottom differential Gear box Assembly [0050] 5: Gear Axle Assembly [0051] 6: End Bearing Housing Assembly [0052] 7: Drill Bit Shaft Assembly [0053] 2.1: Gear Box [0054] 2.2: Spur Gear For Primary Shaft [0055] 2.3: Spur Gear For Secondary Transmission Shaft [0056] 2.4: Primary Input Shaft [0057] 2.5: Secondary Transmission Shaft [0058] 2.6: Bearing Cover for Primary shaft & Secondary Shaft [0059] 2.7: Straight Bevel For Secondary Transmission shaft [0060] 2.8: Straight Bevel for Tertiary shaft [0061] 2.9: Bearing Housing for tertiary shaft [0062] 2.10: Tertiary Shaft [0063] 2.11: Straight Bevel for Differential Gear Box [0064] 3.1: Front Cover Plate [0065] 3.2: Top Cover plate [0066] 3.3: Side cover support plate [0067] 3.4: Front Support square pipe [0068] 3.5: Bracket Plate [0069] 3.6: Bracket cover plate [0070] 3.7: Main gear box mounting flat Bar [0071] 3.8: Protector [0072] 3.9: Lifting Arms [0073] 3.10: Differential gear box fixing plate [0074] 4.1: Differential Gear Box bearing housing [0075] 4.2: Straight Bevel for Differential Gear Box [0076] 4.3: Axle for Differential Gear Box [0077] 4.4: Differential Gear Box Plate [0078] 5.1: Axle [0079] 5.2: Flange for Axle [0080] 5.3: Main spiral Bevel Gear [0081] 5.4: Collar for Main Gear [0082] 5.5: Collar for middle main gear [0083] 6.1: End Bearing Housing [0084] 6.2: Axle for End Bearing Housing [0085] 6.3: End Bearing Housing Cover [0086] 7.1: Drill bit Shaft [0087] 7.2: Drill bit [0088] 7.3: Drill Bit Bearing Housing [0089] 7.4: Spiral bevel gear

[0090] Referring to FIG. 1 to FIG. 6B, present multi drill culti rotavator P comprises; [0091] Differential Gear Box Assembly 2, [0092] Main Body Assembly 3, [0093] Bottom differential Gear box Assembly 4, [0094] Gear Axle Assembly 5, [0095] End Bearing Housing Assembly 6, [0096] Drill Bit Shaft Assembly 7;

[0097] Said differential Gear box Assembly 2 is the main gear box assembly facilitating the plurality of gears in the present invention. It is connected to the main body Assembly 3. Differential Gear box Assembly 2 in turn comprises: [0098] Gear Box 2.1, [0099] Spur Gear for Primary Shaft 2.2, [0100] Spur Gear for Secondary Transmission Shaft 2.3, [0101] Primary Input Shaft 2.4, [0102] Secondary Transmission Shaft 2.5, [0103] Bearing Cover for Primary shaft & Secondary Shaft 2.6, [0104] Straight Bevel for Secondary Transmission shaft 2.7 [0105] Straight Bevel for Tertiary shaft 2.8 [0106] Bearing Housing for tertiary shaft 2.9 [0107] Tertiary Shaft 2.10, [0108] Straight Bevel for Differential Gear Box 2.11

[0109] Referring to FIG. 2; said gear box 2.1 is provided to house the plurality of gears and is connected to Bearing Cover for Primary shaft & Secondary Shaft 2.6 on one side and to Primary Input Shaft 2.4 and Secondary Transmission Shaft 2.5, at the other. Said primary input shaft 2.4 is connected to the power take off shaft of the tractor and takes the input power from the power take off shaft of the tractor and is connected to Bearing Cover for Primary shaft & Secondary Shaft 2.6 on the other side. Secondary Transmission Shaft 2.5 is connected to the Straight Bevel for Secondary Transmission shaft 2.7 and is provided for power transmission. Said Spur Gear for Primary Shaft 2.2, is connected to the Bearing Cover for Primary shaft & Secondary Shaft 2.6. Said Spur Gear for Secondary Transmission Shaft 2.3 is connected to the Bearing Cover for Primary shaft & Secondary Shaft 2.6. Said Bearing Housing for tertiary shaft 2.9 holds Straight Bevel for Tertiary shaft 2.8 and is connected to Tertiary Shaft 2.10 on the other end. Straight Bevel for Tertiary shaft 2.8. Said Tertiary Shaft 2.10 is in turn connected to the Straight Bevel for Differential Gear Box 2.11 on the other end.

[0110] Referring to FIG. 3, said main body Assembly 3 is pentagonal and is attached to the Differential Gear Box Assembly 2 on one side and to Bottom differential Gear box Assembly 4 on the other. The main body Assembly 3, holds the differential gear box assembly 4 and comprises of: [0111] Front Cover Plate 3.1, [0112] Top Cover plate 3.2, [0113] Side cover support plate 3.3, [0114] Front Support square pipe 3.4, [0115] Bracket Plate 3.5, [0116] Bracket cover plate 3.6, [0117] Main gear box mounting flat Bar 3.7 [0118] Protector 3.8, [0119] Lifting Arms 3.9, [0120] Differential gear box fixing plate 3.10;

[0121] Said Front Cover Plate 3.1, Top Cover plate 3.2, Side cover support plate 3.3 and Front Support square pipe 3.4 are provided to cover the Bottom differential Gear box Assembly 4. Said bracket cover plate 3.6 covers the Bracket plate 3.5 attached to Front Support square pipe 3.4. Said Bracket plate 3.5 is provided for fitting the gears on the back side of tractor. Said Gear box 2.1 is mounted over the Main gear box mounting flat Bar 3.7. The protector 3.8 at the either edges of the main body Assembly 3 protects the main body Assembly 3. Said Lifting Arms 3.9 connected to the Front Support square pipe 3.4 are provided to lift the present invention. The Differential gear box fixing plate 3.10 is provided to connect the bottom differential gar box assembly 4.

[0122] Referring to FIG. 4, said Bottom differential Gear box Assembly 4 connected to the Gear Axle Assembly 5 on either sides is provided to control the motion of the present invention. In turn said Bottom differential Gear box Assembly 4 comprises: [0123] Differential Gear Box bearing housing 4.1, [0124] Straight Bevel for Differential Gear Box 4.2, [0125] Axle for Differential Gear Box 4.3, [0126] Differential Gear Box Plate 4.4;

[0127] Said Differential Gear Box bearing housing 4.1, houses Axle for Differential Gear Box 4.3 and Differential Gear Box Plate 4.4 on either sides. Said Differential Gear Box 4.3 is provided to transmit the power from Straight Bevel for Differential Gear Box 4.2 to Gear Axle Assembly 5. Said Differential gear box plate 4.4 is connected to the Straight Bevel for Differential Gear Box 4.2 and is attached to said gear box 2.1. Said Axle for Differential Gear Box 4.3 connects Gear Axle Assembly 5 on both side.

[0128] Referring to FIG. 5, said Gear Axle Assembly 5, is connected to the Bottom differential Gear box Assembly 4. Said Gear Axle assembly 5 consists of plurality of spiral gears more preferably twelve gears; six gears in pair. It is provided to transmit the power from Gear Axle Assembly 5 to End Bearing housing Assembly 6 and further comprises: [0129] Axle 5.1, [0130] Flange for Axle 5.2, [0131] Main spiral Bevel Gear 5.3, [0132] Collar for Main Gear 5.4, [0133] Collar for middle main gear 5.5;

[0134] Said axle 5.1 is connected to the flange for axle 5.2 on one end and to the collar for main gear 5.4 on the other end. Said axle 5.1 is provided for rotating six pair of spiral gears. The flange for axle 5.2 supports the axle 5.1 and collar for main gear 5.4. Said collar for main gear 5.4 houses Main spiral Bevel Gear 5.3. Said Main spiral Bevel Gear 5.3 are in plurality more preferably in pair of six. They translate the force from one direction into another direction with the power of said axle 5.1. Thus they enables the rotation when the rotation of the shafts are interchanged. This enables the rotation in both clockwise as well as anti-clockwise directions.

[0135] Referring to FIG. 6A, said End Bearing housing Assembly 6 is attached to main body assembly 3. Said end bearing housing assembly in turn comprises: [0136] End Bearing Housing 6.1, [0137] Axle for End Bearing Housing 6.2, [0138] End Bearing Housing Cover 6.3;

[0139] Said end bearing housing 6.1 is connected to end bearing housing cover 6.3. Said Axle for End Bearing Housing 6.2 is housed in the end bearing housing 6.1 and is provided to connect with Gear Axle Assembly 5

[0140] Referring to FIG. 6B, said Drill bit shaft Assembly 7 is the main assembly provided to transmit the power from spiral bevel gears to drill bit 7.2 in clockwise and anticlockwise direction and is attached to Bottom differential Gear box Assembly 4. Said drill bit shaft assembly 7 comprises: [0141] Drill bit Shaft 7.1, [0142] Drill bits 7.2, [0143] Drill Bit Bearing Housing 7.3, [0144] Spiral bevel gear 7.4;

[0145] Said Drill bit shaft 7.1 connects the drill bit bearing housing 7.3 and spiral bevel gear 7.4. It further transfers the input power to the said drill bit 7.2. Said spiral bevel gear 7.4 are provided in plurality more preferably six in pair and are in connection with corresponding Main spiral Bevel Gear 5.3. It provides the motion to the present invention P. Said spiral bevel gear 7.4 Said spiral bevel gears 7.4 are in turn connected to the plurality of drill bits 7.2; more preferably twelve drill bits 7.2. Said drill bits 7.2 cultivates and rotavates any and all types of soil including hard soils. Said plurality of drill bits 7.2 are connected to the corresponding rotavation blades (not shown in drawings). Wherein each drill bit 7.2 comprises ploughing section with plurality of rotavator blades preferably three, which are curved on flat on the upper most edge of the drill bit 7.2 at 120° with outward convexity. Said blades are fixed perpendicularly to the drill bits which further will initiate rotation of each in reverse direction than that of the adjoining drill bit; drilling multiple furrows at a time.

Working of Present Invention

[0146] The present Multi drill culti rotavator P, is connected to the power output shaft (PTO) shaft of the tractor and is utilized to cultivate the soil. The working of the present invention further is described herein below:

[0147] Step: 1

[0148] The present invention P works on the power of the tractor and takes the input power from the power take off shaft of the tractor. The input power to the present invention P is transferred by said Primary Input Shaft 2.4 and Secondary Transmission Shaft 2.5.

[0149] The lifting arms 3.9 arises from the either side of the gear box 2.1; projecting upwards and inclining forwards and thus gets attached with the tractor's lifting fork arms. While said lifting arms 3.9 are attached to the tractor's lifting fork arms said Primary Input Shaft 2.4 is connected to the power takeoff shaft of the tractor.

[0150] Step 2

[0151] The input power from the Primary Input Shaft 2.4 and Secondary Transmission Shaft 2.5 is transmitted further to said Spur Gear for Primary Shaft 2.2 and Spur Gear for Secondary Transmission Shaft 2.3.

[0152] Step 3

[0153] The input power than rotates the plurality of Main spiral Bevel Gear 5.3 attached to the corresponding Spiral bevel gear 7.4. Said Main spiral Bevel Gear 5.3 translates the force from one direction into another direction with the power of said axle 5.1. Thus they enables the rotation when the rotation of the shafts are interchanged. This enables the rotation in both clockwise as well as anti-clockwise directions.

[0154] Step 4

[0155] The input power from said Spiral bevel gear 7.4 is transferred to the corresponding plurality of drill bit 7.2 through Drill bit shaft 7.1. The drill bits 7.2 connected to the corresponding rotavation blades initiates rotation of each drill bits 7.2 in reverse direction than that of the adjoining drill bit 7.2; drilling multiple furrows at a time.

[0156] Thus, accordingly the present invention provides a multi-drill Culti-rotavator, composed as described above, would cultivate and rotavate any type of soil and that, in significantly reduced time than by routine tractor cultivation and using significantly less fuel, meaning again significantly reduced pollution. Therefore, it is efficient, economical and easy to operate.

[0157] Comparison of the Efficiency Provided by the Present Invention and Efficiency of Prior Art:

[0158] Cultivation Through Conventional Methods

TABLE-US-00002 TABLE 01 Work Output Cultivation to Per 8 Hours(only Rotavation & single work Seeding Completed Summary Of Time Taken Per Diesel Usage Per cultivation) Units/8 Hours One Day's Acre Vigha Acre Vigha Acres Vigha Acre Vigha Completed Units 2 hours 30 1 hour 30 11.62 7 6 10 1.2 2 31 Litres Per Day min min liters liters Acre Vigha Acre Vigha (8 Hrs) Completing 1.2 Acres/2 Vigha

[0159] Cultivation Through Present Invention:

TABLE-US-00003 TABLE 02 Cultivation to Rotavation & Work Output Seeding Completed Summary Of Time Taken Per Diesel Usage Per Per 8 Hours Units/8 Hours One Day's Acre Vigha Acre Vigha Acres Vigha Acre Vigha Completed Units 1 hour 38 45 mins 5.81 3.5 6.38 10.6 6.38 10.6 37 Litres Per Day min liters liters Acres Vigha Acres Vigha (8 Hrs) Completing 6.38 Acre/10.6 Vigha

[0160] With reference to above table 01, the time taken, fuel required and output generated to cultivate, rotavate and seeding the soil per acre and vigha by the conventional devices and methods is shown. The conventional devices/method can either cultivate or rotavate or seed the soil at a time. Also the time required, fuel consumption and output is much more. With conventional methods/device it shall require 31 liters of fuel per day completing only 1.2 acres/2 Vigha of soil cultivation with an average of 8 working hours.

[0161] Now, referring to table 02, shows the time taken, fuel required and output generated to cultivate, rotavate and seeding the soil per acre and vigha by the present invention P. The present invention cultivates, rotavates and seeds the soil in a single pass. Also the time required, fuel consumption and output is substantially less. The present invention shall require 37 liters of fuel per day completing 6.8 acres/10.6 Vigha of soil cultivation, rotavation and seeding of the soil with an average of 8 working hours. Thus, is substantially efficient, environment friendly, time saving, provides more output and is cost effective.