KR200380578Y1 - Grease feeding device - Google Patents

Abstract

The present invention relates to a grease supply apparatus for simplifying the pumping structure and facilitating easy exchange of grease barrels.

The present invention, the frame is composed of a base surface on which the grease barrel is seated, and a cover provided to be able to move up and down on the base surface; A first vertical member fixed on the base surface, a second vertical member attached to one side of the cover and movable upward and downward with respect to the first vertical member, and an upper end fixed to an upper end of the first vertical member A rack gear, a pinion gear rotatably supported within the second vertical member and meshed with the rack gear, a handle integrally connected on the coaxial line of the pinion gear, a lower end fixed to the base surface, and an upper end being the first vertical A lifting mechanism comprising a damper member fixed to the inner lower surface of the member and installed in the vertical direction; A pumping mechanism penetrating into the outer cylinder of the frame to pump grease in the grease cylinder and pump the grease to the outside; And a drive for driving the pumping mechanism.

Description

Grease feeding device

The present invention relates to a grease supply device, and more particularly, to a grease supply device for simplification of a pumping structure and easy exchangeability of a grease container.

Grease is a kind of lubricating oil used in semi-solid state. It is mainly used in the part where lubricating oil is difficult to be injected. It shows liquid state during movement, and when it stops, it loses its mobility and becomes semi-solid state.

These greases have a variety of products depending on their use and composition. Most of these greases are prepared by adding a metal soap and a small amount of water to a liquid mineral oil-based lubricant and mixing them in a colloidal state. When friction deformation is caused by the movement of the machine or the temperature rises, oil in the inside leaks outwardly, and it is used in the friction part where the load of the rotating shaft against the bearing is large, and the part which is difficult to refuel. Recently, synthetic oils such as silicone oil are also used instead of mineral oils, and fatty acid salts such as calcium, aluminum, and lithium are frequently used for metal soaps.

On the other hand, various apparatuses for automatically supplying such greases automatically or manually to a place requiring lubrication in various production facilities such as a vehicle manufacturing facility or an ironworks are disclosed or implemented.

FIG. 1 shows a conventional electric grease supply device which is frequently used for steel making facilities or transportation facilities. The conventional electric grease supply device includes an electric grease pump 10 and two greases fed from the pump 10. It consists of a reversing valve 30 to alternately switch through the supply pipe 20, and a grease charge pump 40 is filled with a predetermined amount of grease. Here, reference numeral 50 denotes a control panel, 60 denotes a distribution valve, 70 denotes a supply pipe, and 80 denotes an oil supply pipe.

The conventional grease supply device is a device for automatically supplying a predetermined oil supply interval to the system timer of the electric control panel 50. For this purpose, the grease fed from the pump 10 is alternately replaced by the reversing valve 30. When the fuel is switched to the oil supply points through the two supply pipes 20 and the distribution valves 60, and at the same time, the pressure of the supply pipes 20 rises rapidly and exceeds the set pressure of the reversing valve 30. As the reversing valve 30 is switched, lubrication is made through the opposite supply main line 20.

However, in the conventional grease supply apparatus, since a grease charge pump 40 for supplying grease to the grease pump 10 must be separately installed, the manufacturing cost not only increases, but also takes up a lot of mounting space. There was a drawback to contamination.

Accordingly, Korean Patent Publication No. 0158082 discloses a configuration in which a grease pump is provided with a lifting means to remove a separate grease charge pump.

However, the above-mentioned domestic registered patent publication No. 0158082 has a risk that the lifting means may suddenly descend when the lifting means is lowered and lowered to replace the grease barrel, which may cause damage to the entire apparatus. In addition, the lifting means is made of a complex structure has a disadvantage that the lifting operation is very cumbersome.

In addition, the above-mentioned Korean Patent Publication No. 0158082 has a complicated configuration of a pumping unit for pumping grease in a grease container, which increases the manufacturing cost thereof, and also has a disadvantage in that replacement and repair of the pumping unit is very difficult.

The present invention has been made in view of the above, the main purpose is to provide a grease supply device that can facilitate the replacement workability of the grease container.

In addition, the present invention has a further object to provide a grease supply device that can simplify the pumping structure to lower the manufacturing cost thereof, and also to facilitate replacement and repair of each pumping mechanism.

The present invention for achieving the above object,

A frame including a base surface on which a grease barrel is seated, and a cover provided to be movable up and down at an upper portion of the base surface;

A first vertical member fixed on the base surface, a second vertical member attached to one side of the cover and movable upward and downward with respect to the first vertical member, and an upper end fixed to an upper end of the first vertical member A rack gear, a pinion gear rotatably supported within the second vertical member and meshed with the rack gear, a handle integrally connected on the coaxial line of the pinion gear, a lower end fixed to the base surface, and an upper end being the first vertical A lifting mechanism comprising a damper member fixed to the inner lower surface of the member and installed in the vertical direction;

A pumping mechanism penetrating into the outer cylinder of the frame to pump grease in the grease cylinder and pump the grease to the outside;

And a drive for driving the pumping mechanism.

Preferably, the damper member is set to have an allowable pressure corresponding to the total load of the lid, the driving portion and the pumping mechanism.

Preferably, a guide tool having a through hole is fixedly installed on the lower inner surface of the second vertical member of the lifting mechanism, and a lower end of the guide bar is fixedly installed on the upper surface of the base surface, and the through hole of the guide tool is formed on the outer circumferential surface of the guide bar. It is configured to guide the ride.

Preferably, the cover consists of a circular top plate member and a side member detachably coupled to the lower side of the top plate member by a locking mechanism.

Preferably, the locking mechanism includes a plurality of locking jaws provided on the outer circumferential surface of the upper plate member, and a plurality of hooks that are rotatably provided at the upper end side of the side member to be engaged with each locking jaw.

Preferably, the drive unit comprises a drive motor mounted on the upper surface of the upper plate member, an electric drive for transmitting the driving force of the drive motor, and a connecting shaft connected on the output shaft of the electric drive.

Preferably, the pumping mechanism pumps the grease in the grease barrel by interlocking with the pump frame connected to the center of the upper plate member of the cover by the supporter, the cam member connected to the lower end of the connecting shaft, and the cam member and the cam member. At least one pumping unit for pumping to the outside.

Preferably, the cam member is disposed in the pump frame, and includes a rotating shaft connected to the lower end of the connecting shaft of the drive unit and an eccentric rotating body integrally formed with the rotating shaft, the eccentric rotating body having a disk shape, the center of which is the center of the rotating shaft. In the form of the eccentric by a predetermined distance from the eccentric rotation by the rotation operation of the rotary shaft.

Preferably, a plurality of stirring blades may be connected to the lower end of the rotating shaft of the cam member.

Preferably, the pumping unit includes a cylinder member fixed to one side of the pump frame, a grease flow passage formed inside the cylinder member for distributing grease, and slidably supported by a spring member while being slid to the eccentric rotating body. A piston rod operating forward and backward into the distribution passage, a check valve installed in the middle of the grease distribution passage to prevent backflow of grease, at least one grease suction hole for sucking the grease into the grease distribution passage, and a grease outside the grease distribution passage. It includes a grease outlet hole for outflow.

Preferably, a safety valve is further provided to maintain the grease discharge pressure at an appropriate level in the middle of the grease discharge hose extending from the grease outlet hole to the adapter mounted on the upper surface of the upper plate member.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail.

2 to 5 show a grease supply apparatus according to an embodiment of the present invention.

As shown, the grease supply device of the present invention is arranged on one side of the frame 100 and the frame 100 for sealingly seating the grease-filled grease container 105 to replace the grease container 105. And a lifting mechanism 200 for facilitating, a pumping mechanism 300 for pumping grease in the grease barrel 105 to be pumped to the outside, and a driving unit 400 for driving the pumping mechanism 300.

The frame 100 is composed of a base surface 101 on which a grease barrel 105 is mounted, and a lid 102 provided on the base surface 101 to be lifted up and down.

A grease cylinder 105 is seated on the upper surface of the base surface 101, and a lifting mechanism 200 and a reversing valve 150, which will be described later, are provided.

The cover 102 is installed on the upper surface of the base surface 101 so as to be lifted up and down to seal the grease container 105 seated on the base surface 101 so that foreign matters are introduced into the grease container 105. To prevent grease contamination.

The cover 102 is composed of an upper plate member 102a having a disk shape and a side member 102b detachably coupled to the lower surface of the upper plate member 102a by a locking mechanism 103.

The locking mechanism 103 is rotatably provided at a plurality of locking jaws 103a provided on the outer circumferential surface of the upper plate member 102a and the upper end side of the side member 102b to be engaged with each locking jaw 103a. It consists of a locking ring (103b).

The drive unit 400 is configured to rotate and drive the cam member 303 of the pumping mechanism 300 to be described later, the drive motor 401 mounted on the upper surface of the upper plate member 102a, and the drive motor 401. It consists of an electric mechanism 402, such as a gear transmission train which transmits the driving force of the, and the connecting shaft 403 connected on the output shaft of this electric mechanism 402.

In addition, a supporter 405 supporting the pump frame 301 of the pumping mechanism 300 to be described later is fixedly installed on the central lower surface of the upper plate member 102a, and the supporter 405 has a tubular shape and has an inner hollow. The connecting shaft 403 described above is inserted and arranged on the portion.

In addition, an adapter 109 having a pressure gauge 106 is installed on one upper surface of the upper plate member 102a, and the adapter 109 is formed with a flow path having an inlet port and an outlet port therein. A grease discharge hose 110 extending from the pumping unit 304 of the pumping mechanism 300 is connected to the port, and a grease discharge hose extending to the grease inlet hole 151 of the reversing valve 150 is connected to the outlet port. 110 is in communication.

In addition, a grease recovery hole 107 is formed in another upper side surface of the upper plate member 102a, and the grease recovery hole 107 is used for grease recovery extending from the recovery port 152 of the reversing valve 150. Lake 108 is in communication. On the other hand, the grease recovery hole 107 is disposed adjacent to the open upper surface of the grease container 105 located inside the cover 102, whereby the grease transferred through the grease recovery hose 108 is grease It is recovered into the grease barrel 105 through the recovery hole 107.

Lifting mechanism 200 is configured to raise and lower the cover 102, the first vertical member 201 installed in the vertical direction on the upper surface of the base surface 101, and attached to one side of the cover 102, the first A second vertical member 202 provided to be movable upward and downward with respect to the vertical member 201, a rack gear 203 having an upper end fixed to an upper end of the second vertical member 202, and a first vertical member ( The pinion gear 204 which is rotatably supported in the inner space of the 201 and meshes with the rack gear 203, the handle 205 integrally connected on the coaxial line of the pinion gear 204, and the lower end portion of the base surface ( At the same time, the upper end portion includes a damper member 206 fixed to the inner lower surface of the second vertical member 202 and installed in the vertical direction.

The first vertical member 201 is formed in a columnar shape and is elongated in the vertical direction on the upper surface of the base surface 101, and the second vertical member 202, which will be described later, slides on one side thereof.

The second vertical member 202 is formed in a channel shape in which one end of the upper end protrudes in the horizontal direction, and is installed to move in the vertical direction while sliding on one side of the first vertical member 201 described above, and the bracket 208 It is fixedly coupled to one side of the upper plate member (102a) of the cover 102 through the.

Preferably, the lower inner surface of the second vertical member 202 is fixed to the guide hole 202a having a through hole, the lower end of the guide rod 202b is fixed to the upper surface of the base surface 101 As the through hole of the guide tool 202a is guided on the outer circumferential surface of the guide rod 202b, it is possible to more accurately guide the shanghai-dong of the second vertical member 202.

The rack gear 203 is fixed to the protruding upper end of the second vertical member 202 and is installed through the first vertical member 201.

The pinion gear 204 is rotatably supported in the inner space of the first vertical member 201 and is engaged with the rack gear 203 described above.

The handle 205 is rotatably supported on the outer surface of the first vertical member 201 and is connected integrally on the coaxial line of the pinion gear 204 as described above, thereby turning the handle 205 to turn the pinion gear 204. Also rotate together in the same direction.

The damper member 206 is a kind of various types of shock absorbing or boosting mechanisms such as a dash port, a buffer, a shock observer, a stay damper, etc., and a cylinder 206a filled with fluid such as oil or air therein, and the cylinder ( A piston (not shown) slid in 206a and a piston rod 206b extending outwardly from the piston (not shown), and a plurality of small diameter orifices are formed in the piston.

When the damper member 206 exerts an external force on the piston rod 206b side, the fluid moves from one space inside the cylinder 206a compressed by the piston to the other space through the orifice of the piston. And at the same time serves to support the second vertical member 202 and the cover 102 at a specific height.

By the structure of the lifting mechanism 200, when the user wants to elevate the cover 102 of the frame 100 upward, when the user turns the handle 205 in a predetermined direction, the above-described rack gear and pinion gear 203 As the 204 are engaged with each other, the rack gear 203 is moved upward, and accordingly, the second vertical member 202 is also moved upward, so that the cover 102 is elevated upward.

Here, when the user rotates the handle 205, the back pressure is generated on the second vertical member 202 side by the pressure of the fluid filled in the cylinder 206a of the damper member 206, so that the handle 205 is made small. Even when turned by force, the second vertical member 202 and the cover 102 are raised smoothly.

When the cover 102 of the frame 100 is raised to a certain height, when the hand is released from the handle 205 (that is, no external force is applied to the handle 205 side), the second vertical member 202 and The lid 102 is no longer moved by being supported by the pressure of the fluid filled in the cylinder 206a of the damper member 206.

In this state, when replacing the grease container 105 with a new one between the cover 102 and the base surface 101 and then lowering the cover 102, the handle 205 is rotated in the opposite direction to the rack described above. As the gears and pinion gears 203 and 204 are meshed with each other, the rack gear 203 is moved downward, and accordingly, the second vertical member 202 is also moved downward so that the cover 102 is lowered. .

Here, when the user rotates the handle 205 in the opposite direction, the lifting force acts on the second vertical member 202 side by the pressure of the fluid filled in the cylinder 206a of the damper member 206 and the second vertical member. The 202 and the cover 102 are prevented from descending sharply, and are slowly lowered smoothly.

In this way, the lifting mechanism 200 of the present invention has a feature that can prevent the cover 102 is sharply lowered by the damper member 206 to damage the grease barrel 105 or the pumping mechanism 300 described later have.

On the other hand, the damper member 206 is set so as to have the cover 102 mentioned above, the drive part 400 provided in this cover 102 side, and the allowable pressure corresponding to the total load of this pumping mechanism 300. Would be desirable.

The pumping mechanism 300 is configured to be connected to the upper plate member 102a of the cover 102 to be inserted into the grease barrel 105.

The pumping mechanism 300 includes a pump frame 301 connected to the center lower surface of the upper plate member 102a of the cover 102 via a supporter 405, and a cam member connected to a lower end of the connecting shaft 403 to cam motion. 303 and at least one pumping unit 304 for pumping the grease in the grease barrel 105 to the outside in conjunction with the cam member 303.

The pump frame 301 is configured to be connected to the cover 102 by being coupled to the lower end of the supporter 405 fixed to the central lower surface of the upper plate member 102a of the cover 102.

The cam member 303 is disposed in the pump frame 301 and includes a rotary shaft 303a connected to the lower end of the connecting shaft 403 of the drive unit 400 and an eccentric rotor 303b integrally formed on the rotary shaft 303a. The rotary shaft 303a is rotatably supported by a bushing 302 mounted in the pump frame 301, and the eccentric rotor 303b has a disk shape, the center of which is predetermined from the center of the rotary shaft 303a. The eccentric rotating body 303b is eccentrically rotated by the rotational operation of the rotating shaft 303a by being eccentric by the distance.

Preferably, a plurality of stirring blades 310 may be connected to the lower end of the rotating shaft 303a of the cam member 303. The stirring blade 310 rotates with the cam member 303 to properly stir the grease in the grease barrel 105.

The pumping unit 304 includes a cylinder member 304a fixed to one side of the pump frame 301, a grease flow passage 304b formed in the cylinder member 304a to distribute grease, and an eccentric rotating body. A piston rod 304c which is in contact with 303b and operates back and forth into the grease flow passage 304b, a check valve 304d installed in the middle of the grease flow passage 304b, and prevents backflow of grease, and a grease flow passage At least one grease suction hole 304e for sucking grease into 304b, and a grease outlet hole 304f for leaking grease out of the grease flow passage 304b.

The cylinder member 304a is fixedly installed on one side of the pump frame 301, and the front side thereof is inserted into the pump frame 301, and the rear side thereof is installed to be exposed to the outside of the pump frame 301.

The grease flow passage 304b is formed as a predetermined path inside the cylinder member 304a, and the piston rod 304c moves forward and backward on the opening side formed at one end thereof, and the closing member 304g at the opening formed at the other end thereof. Closed by).

The piston rod 304c slides with the eccentric rotating body 303b of the cam member 303 in which the front end of the free end thereof is eccentrically rotated, and the rear face of the free end is elastically supported by the spring member 304h. As a result, the piston rod 304c reciprocates linearly in the front and rear directions by the eccentric rotation of the eccentric rotating body 303b. That is, the cam member 303 and the pumping unit 304 are a kind of cam motion mechanism for converting the rotational motion of the cam member 303 into the reciprocating linear motion of the piston rod 304c.

The grease suction hole 304e is formed in communication with one side of the grease flow passage 304b to introduce grease into the grease flow passage 304b.

The grease outlet hole 304f is formed in communication with the other side of the grease flow passage 304b to allow the grease introduced into the grease flow passage 304b to flow out, and the grease outlet hole 304f has a grease discharge hose ( 110 is connected, and the grease discharge hose 110 passes through the adapter 109 installed on the upper surface of the upper plate member 102a of the cover 102, and then the grease inlet port of the reversing valve 150 to be described later ( 151).

Preferably, a safety valve that maintains the grease discharge pressure at an appropriate level in the middle of the grease discharge hose 110 extending from the grease outlet hole 304f to the adapter 109 mounted on the upper surface of the upper plate member 102a. 115 may be further provided.

The check valve 304d prevents the grease from flowing back from the grease outlet hole 304f side to the grease suction hole 304e side, and various forms may be applicable in addition to the form shown in the drawing.

When the driving motor 401 of the driving unit 400 is driven by the configuration of the pumping mechanism 300, the driving force of the driving motor 401 is transmitted to the connecting shaft 403 through the transmission mechanism 402. The connecting shaft 403 is driven to rotate at a rotational speed of, and the cam member 303 also rotates in conjunction with this.

The rotation of the cam member 303 is converted into an eccentric rotational movement of the eccentric rotational body 303b, and the piston rod 304c moves forward and backward linearly by the eccentric rotational movement of the eccentric rotational body 303b. .

When such a piston rod 304c protrudes from the cylinder member 304a (i.e., during the forward operation of the piston rod 304c), the piston rod 304c forms a predetermined space in the grease flow passage 304b. The negative pressure is generated in the space thus formed, and the grease in the grease cylinder 105 is sucked into the grease flow passage 304b through the grease suction hole 304e.

Next, when the piston rod 304c enters the cylinder member 304a (i.e., in the reverse operation of the piston rod 304c), the rear end of the piston rod 304c is sucked into the grease flow passage 304b. The grease is pushed out and discharged through the grease outlet hole 304f.

The grease discharged through the grease outlet hole 304f is introduced into the inlet port 151 of the reversing valve 150 through the grease discharge hose 110 and then the discharge port 153 of the reversing valve 150. It is supplied to the necessary place through the outside.

The reversing valve 150 is installed on one upper surface of the base surface 101, and a grease inflow port 151 communicating with a grease discharge hose 110 extending from the pumping mechanism 300, and a cover 102. A grease recovery port 152 through which a grease recovery hose 108 communicates with a grease recovery hole 107 formed on the upper plate member 102a of the cuff), and a plurality of discharge ports 153 for supplying grease to an external required location. And an adjustment screw 154 for appropriately setting the discharge pressure of the grease.

The reversing valve 150 receives the grease discharged from the pumping unit 300 through the inlet port 151 and then supplies it to an external necessary place through the plurality of discharge ports 153 by selective direction control. When the discharge pressure of the grease discharged from the pumping mechanism 300 exceeds the discharge pressure set by the adjustment screw 154, the grease is transferred to the upper plate member through the grease recovery port 152 and the grease recovery hose 108. It is supplied to the grease recovery hole 107 side of 102, and it is comprised so that it may be collect | recovered in the grease container 105. FIG.

The operation relationship of the present invention configured as described above will be described in detail as follows.

First, the cover 102 is raised and lowered by operating the handle 205 of the lifting mechanism 200, and then the grease barrel 105 is seated between the base surface 101 and the cover 102, and then the lifting mechanism 200 is lifted. By operating the handle 205 in the reverse direction to lower the cover 102, the grease container 105 is securely sealed in the cover 102.

In this state, when driving the drive motor 401 of the drive unit 400, the driving force of the drive motor 401 is transmitted to the cam member 303 via the transmission mechanism 402, connecting shaft 403, The rotating shaft 303a of the cam member 303 is driven to rotate.

As the rotation shaft 303a of the cam member 303 rotates, the eccentric rotating body 303b of the cam member 303 makes an eccentric rotational movement, and the pumping unit 304 sliding to the eccentric rotating body 303b. Piston rod (304c) of the) is to make a linear reciprocating motion in the front and rear direction corresponding to the eccentric rotation of the eccentric rotating body (303b).

The linear reciprocating motion of the piston rod 304c sucks the grease in the grease barrel 105 into the grease flow passage 304b formed in the cylinder member 304a of the pumping unit 304 and then discharges the grease hose 110. Through the discharge valve 150 to the side.

The reversing valve 150 receives grease discharged from the pumping unit 300 through the inlet port 151 and then selectively controls the supply of the grease discharged from the pumping unit 300 to an external necessary location through the plurality of discharge ports 153. do.

On the other hand, when the discharge pressure of the grease discharged from the pumping mechanism 300 exceeds the discharge pressure set by the adjustment screw 154, the grease is the upper plate member through the grease recovery port 152 and the grease recovery hose 108 It is supplied to the grease recovery hole 107 side of 102 and is recovered into the grease container 105.

The present invention as described above has the effect of making it easier to replace the grease container.

In addition, the present invention has the advantage of simplifying the pumping structure to lower the manufacturing cost thereof, and also to facilitate replacement and repair of each pumping mechanism.

In the above, the present invention has been shown and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiment, and those of ordinary skill in the art to which the present invention belongs, without departing from the spirit of the technical idea of the present invention described in the utility model registration claims below. Various changes can be made.

1 is a view showing an installation state of a typical grease supply device.

Figure 2 is a plan view showing a grease supply apparatus according to an embodiment of the present invention.

3a and 3b is a front view showing a grease supply apparatus according to an embodiment of the present invention.

4 is a view showing a pumping mechanism of the grease supply apparatus according to an embodiment of the present invention.

FIG. 5 is a rear view of the lifting mechanism shown along arrow A of FIG. 3B.

Brief description of symbols for the main parts of the drawings

100 frame 105: grease container

200: lifting mechanism 300: pumping mechanism

400 drive unit

Claims (11)

A frame including a base surface on which a grease barrel is seated, and a cover provided to be movable up and down at an upper portion of the base surface; A first vertical member fixed on the base surface, a second vertical member attached to one side of the cover and movable upward and downward with respect to the first vertical member, and an upper end of the first vertical member attached to the first vertical member; A fixed rack gear, a pinion gear rotatably supported in the second vertical member and meshed with the rack gear, a handle integrally connected on the coaxial line of the pinion gear, and a lower end fixed to the base surface, A lifting mechanism comprising a damper member fixed to the inner lower surface of the vertical member and installed in the vertical direction; A pumping mechanism penetrating into the outer cylinder of the frame to pump grease in the grease cylinder and pump the grease to the outside; And a drive unit for driving the pumping mechanism. The method of claim 1, And the damper member is set to have an allowable pressure corresponding to the total load of the cover, the driving portion, and the pumping mechanism. The method according to claim 1 or 2, A guide tool having a through hole is fixedly installed on a lower inner surface of the second vertical member of the lifting mechanism, and a lower end of the guide rod is fixedly installed on an upper surface of the base surface, and the through hole of the guide tool is guided through the outer circumferential surface of the guide bar. Grease supply apparatus, characterized in that configured. The method of claim 3, And the lid is formed of a circular upper plate member and a side member detachably coupled to a lower side of the upper plate member by a locking mechanism. The method of claim 4, wherein The locking mechanism is a grease supply device comprising a plurality of locking jaw provided on the outer circumferential surface of the upper plate member, and a plurality of locking hooks rotatably provided at the upper end side of the side member to engage each locking jaw. The method of claim 5, And the drive unit comprises a drive motor mounted on the upper surface of the upper plate member, an electric drive for transmitting the driving force of the drive motor, and a connecting shaft connected to the output shaft of the electric drive device. The method of claim 6, The pumping mechanism includes a pump frame connected to a central lower surface of the upper plate member of the cover by a supporter, a cam member connected to a lower end of the connecting shaft, and a cam member connected to the cam shaft, and pumped grease in the grease barrel in conjunction with the cam member to be pumped to the outside. A grease supply apparatus comprising at least one pumping unit. The method of claim 7, wherein The cam member is disposed in the pump frame, and includes a rotating shaft connected to the lower end of the connecting shaft of the driving unit and an eccentric rotating body integrally formed with the rotating shaft. The eccentric rotating body has a disk shape, the center of which is a predetermined distance from the center of the rotating shaft. The grease supply device is characterized in that the eccentric rotation by the rotation operation of the rotating shaft made of an eccentric form. The method of claim 8, Grease supply device, characterized in that a plurality of stirring blades are connected to the lower end of the rotating shaft of the cam member. The method of claim 9, The pumping unit includes a cylinder member fixed to one side of the pump frame, a grease flow passage formed inside the cylinder member to distribute grease, and an eccentric rotating body and elastically supported by a spring member into the grease flow passage. A piston rod that operates forward and backward, a check valve installed in the middle of the grease flow passage to prevent backflow of grease, at least one grease suction hole for suctioning grease into the grease flow passage, and a grease flow out of the grease flow passage. A grease outlet hole; And a grease discharge hose communicates with the grease outlet hole. The method of claim 10, A grease supply device, further comprising a safety valve which maintains a grease discharge pressure at an appropriate level in the middle of the grease discharge hose.