KR20170061090A - Pump for supplying an application system of a liquid covering product - Google Patents

Abstract

A pump (1) for supplying an application system of a liquid cover product comprises a motor (3) for operating at least two pistons, a drum (9) rotated by a motor (3) And each piston is fixed to the rolls 51 and 61 which are fixed and rolling on the cam profile 92 with rollers 53 and 63 so that one of the rods Through which the rollers connected to each of the pistons are translated along the translational axis (X-X ') of the corresponding piston under the action of the rotation of the drum (9). Each of the rollers is in contact with the cam profile at an offset position relative to the position of the other rollers and one of the pistons is moving when the other piston reaches the point of reversal of the direction of motion. The pump includes compensation means (10) suitable for accelerating one of the pistons when the other piston reaches the point of reversal of its direction of motion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pump for supplying an application system of a liquid cover product,

The present invention relates to a pump for supplying an application system of a liquid cover product.

BACKGROUND OF THE INVENTION [0002] Pumps for supplying application systems for liquid cover products such as paints generally consist of electric or pneumatic motors, hydraulic pumps and coupling means for connecting the motor to the pump. The electric pump will refer to a pump having a feed pump with an electric motor and a pneumatic pump, a pneumatic motor. Electric pumps are preferably used because of better performance and lower use costs. The problem is in converting the motion between an electric motor with rotational motion and a hydraulic pump with alternating linear motion. When the direction of motion reverses, the piston of the hydraulic pump reaches zero speed, which causes a drop in pressure at the outlet of the pump. Thus, the electric pump must be provided to offset such a reversal.

Pumps comprising a single piston operated by a connecting rod-crank system are known. In this pump, the rotational speed of the electric motor is controlled to obtain a constant flow rate. A pump comprising a single piston operated by a rack is known from US-A-2015/219819. To reverse that wear is reversed for the different teeth of the rack. None of these systems can avoid a pressure drop at the outlet of the pump.

Wherein the movement is caused by rotation of the cam in the form of a heart and the profile and associated mechanism is configured such that during the reversal of one of the movements of the piston the other piston is not completely at the end of its movement, It is also known to use pumps that are phase shifted by Pi radians. However, such a system is not entirely satisfactory in view of the fact that it involves a continuous change in the torque provided by the motor. Furthermore, in the design of the known heart-shaped cam, the latter has only one means for pushing the piston of the hydraulic pump; A return mechanism is needed to achieve movement of the piston in the opposite direction.

The present invention seeks to overcome this disadvantage by suggesting a new pump for supplying an application system of a liquid cover product that allows more effective compensation of the reversal of the piston of the pump.

To this end, the invention relates to a pump for supplying an application system of a liquid cover product comprising a motor for operating at least two pistons. This pump comprises a drum which is rotated by a motor and which comprises an outer cylinder surface with a cam profile, each piston being fixed on a rod which is fixed on the cam profile and rolls, The roller being connected to each of the rollers is translated along the translational axis of the corresponding piston under the action of rotation of the drum, each roller being in contact with the cam profile at a position offset at an angle to the position of the other roller, And one of the pistons when the other piston reaches the point of reversal of its direction of motion.

Due to the invention, the acceleration of one of the pistons during the reversal of the other piston enables effective compensation of the pressure drop. The pressure obtained at the outlet of the pump is generally constant.

According to an advantageous but optional aspect of the present invention, such a pump can incorporate one or more of the following features in view of any technically acceptable combination.

The compensating means comprises means for accelerating the rotational speed of the drum for a predetermined length of time before and after passage of one of the pistons by its point of reversal: in this embodiment, at the time of reversal, during the torque reduction The rotational speed of the motor increases, and the electric power required from the motor is kept constant.

The acceleration means comprises a control unit of the motor.

The compensation means comprise a pressure sensor arranged downstream from the piston and the acceleration means being suitable for increasing the rotational speed of the drum as a function of the pressure value measured by the pressure sensor.

The compensating means is formed by two angular sectors of the cam profile having an inclination angle with respect to a plane perpendicular to the axis of rotation of the drum, which is greater than the inclination angle of the remaining angular sector of the cam profile. In this embodiment, compensation is performed while maintaining a constant speed and motor torque.

The inclination angle of the angular sector of the cam profile forming the compensation means is twice the inclination angle of the remaining angular sector of the cam profile.

The pump includes two pistons offset at an angle of 90 [deg.].

The cam profile comprises two helical slots each extending over half the circumference of the drum and symmetrical about a plane passing through the axis of rotation of the drum.

The rollers are offset by angles comprised between 70 ° and 100 °.

- The offset angle of the rollers is 90 °.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be better understood and other advantages will become more apparent in the light of the following description of a feed pump according to its principle, which is provided by way of non-limiting example with reference to the attached drawings.
1 is a perspective view of a pump according to a first embodiment of the present invention.
2 is an enlarged view of detail II of Fig.
Figure 3 is a top view of the pump of Figures 1 and 2;
4 is a sectional view taken along the plane IV-IV of FIG.
5 is a curve showing the change in rotational speed as a function of the ring position of the motor of the pump of Figs.
Figure 6 is a view similar to the enlarged view of Figure 4 of a pump according to a second embodiment of the present invention, in which only the drum and roller of the pump are shown.
Figure 7 is a view similar to Figure 1 of a pump according to a third embodiment of the present invention.

1 to 5 show a pump for supplying an application system of a liquid cover product not shown. The pump 1 includes an electric motor 3 having a rotation axis X-X '.

The motor operates two pistons 5, 6 respectively mounted to the chamber 8 with the possibility of sliding along each axis X5 and X6 parallel to the axis X-X '. The movement of the pistons 5, 6 in the chamber 8 makes it possible to deliver pressurized liquid cover products such as paint.

The motor 3 operates the pistons 5, 6 through a delivery system comprising a drum 9 rotated by a motor 3 about an axis X-X '. The transmission of rotation from the motor 3 to the drum 9 may be direct or indirect through a gear reduction system not shown.

The drum 9 includes an outer cylinder surface 90 centered on the axis X-X '. The outer surface 90 has a cam profile 92. Each of the pistons 5 and 6 is fixed to the first rod 51 and the second rod 61 to which the first roller 53 and the second roller 63 are fixed respectively and the respective rollers 53, 63 are rolled over the cam profile 92 so that each roller 53, 63 connected to each of the pistons 5, 6 via the rods 51, 61 under the action of the rotation of the drum 9, -X '. ≪ / RTI >

In the illustrated example, the cam profile 92 includes two spiral slots 94, 95, each extending over half the circumference of the drum 9 and symmetrical about plane P1 passing through the rotation axis X-X 'of the drum As shown in Fig. Each slot 94,95 includes a bottom 94a and 95a of each cylinder, upper spiral walls 94b and 95b and lower spiral walls 94c and 95c. The rollers 53 and 63 selectively contact the upper (94b, 95b) or lower (94c, 95c) helical wall along a contact line perpendicular to the axis X-X '.

In Fig. 4, the motor 3, the drum 9 and the rollers 53 and 63 appear twice due to the geometry of the cutting plane IV-IV.

Contact between the spiral walls 94b, 95b, 94c and 95c and the rollers 53 and 63 when the drum 9 itself rotates about the axis XX ' 61, which alternately enables the absorption of the cover product and then its pressurized release at the outlet of the pump 1 to be achieved.

Each of the pistons 5, 6 has a top floating center and a bottom floating center corresponding to the point of reversal of the direction of translation thereof. During this reversal, the linear velocity of the pistons 5, 6 decreases and then passes through a zero value, which causes a blockage of the pressure at the outlet of the pump. It is therefore necessary to offset the deceleration of the speed of one of the pistons 5, 6 when it reaches its reversing point with the movement of the other piston. Therefore, according to the present invention, the contact point of one of the cam profile 92 and the rollers 53, 63 is offset at an angle relative to the position of the contact point of the other roller, One of the pistons 5, 6 is in motion. Advantageously, as shown in Fig. 4, each positioning of the rollers 53, 63 allows the roller 53 to reach its top reversal point while the roller 63 is approximately midway through its upward movement . This makes it possible to partially offset the pressure drop due to the reversal of the piston.

The offset angle A of the rollers 53 and 63 is preferably comprised between 70 and 100 degrees. Preferably, the offset angle A of the roller is 90 [deg.]. This angle A is also an angle formed by the axes X5 and X6 with respect to the axis X-X '. Since the pistons 5, 6 may reach their reversing point at the same time and may not be offset from one another, the offset may not be 180 degrees.

3, the rollers 53 and 63 are offset by a quarter turn of the drum 9, which causes the rollers 53 to rotate while the roller 63 reaches the center portion of the slot 95. Thus, Means reaching the boundary between the slots 94 and 95, which corresponds to half of the movement of the piston 6.

In order to more effectively compensate the reversal of the piston, according to the invention, the pump 1 comprises suitable compensation means for accelerating one of the pistons 5, 6 while the other piston reaches its reversing point.

According to a first embodiment of the invention, the compensating means is connected to the control unit 10, schematically shown in figure 1, for a predetermined length of time before and after the passage of one of the pistons 5, 6 by its reversing point And means for accelerating the rotational speed of the drum 9 formed by the drum. Thus, during the entire cycle in which one of the pistons is decelerated, passed through zero speed and accelerated again, the rotational speed of the drum 9 is accelerated by the control unit 10 to enable compensation of the deceleration of the first piston The translational speed of the other piston is also accelerated. This method is represented by the curve shown in Fig. 5, which shows the change of the rotational speed V of the drum 9 as a function of the angular position of the drum 9. Fig. The velocity profile is transmitted to the motor 3 by the control unit 10 in the form of an electric signal S10. In each quarter rotation of the drum 9, corresponding to a rotation of Pi / 2 radians, a reversal of the piston 5 or 6 occurs, which leads to compensation by an increase in the velocity V around this angular position .

By way of example, the rotational speed of the drum 9 may be increased at 5 revolutions per minute (RPM).

The control unit 10 is preferably an electronic unit that performs dependent control of the rotational speed of the motor 3. [

By way of example, the angular spacing of the piston before and after the reversal point of the piston, during which the speed of the drum 9 is increased, may be comprised between 0.14 and 0.28 radians.

A second embodiment of the present invention is shown in Fig. In this embodiment, elements shared with the first embodiment have the same reference and operate in the same way. Only differences with respect to the first embodiment are described below.

In Fig. 6, only the drum 9 and the rollers 53, 63 at the two positions in the sectional view of Fig. 4 are shown in consideration of clarity.

6, the compensating means is arranged to compensate for the rotation axis X-X, which is nominally referred to as the remaining angular sector of the cam profile 92, in place of or in addition to the means for accelerating the rotational speed of the drum 6. [ 'Of the cam profile 92 that is greater than the slope angle A92 as measured relative to the plane P2 perpendicular to the slope angle A'. The remaining angular sector is defined as part of the cam profile 92 extending out of the angle sector 97. The angled sectors 97 with the emphasized inclination are disposed on the respective central portions of the slots 94 and 95. Thus, the rollers 53 and 63 are offset by 90 degrees so that the roller 53 is in contact with the angle sector 97 as shown in the left side of Fig. 6, while the roller 63 is in contact with the angle sector 97 as shown in the right side of Fig. As well as reaching the point of reversal. In this way, the translational velocity along the axis X-X 'of the roller 63 is accordingly increased due to the increase in the inclination of the walls 94b, 95b, 94c and 95c. Thus, the acceleration of the piston 6 fixed to the roller 63 offsets the deceleration and passage by the zero speed of the piston 5. [ This makes it possible that the fact that one of the pistons 5, 6 has reached its reversing point causes only a relatively small change in the outlet pressure of the pump 1.

According to one advantageous but optional aspect of the invention, the value of the tilt angle A97 is preferably twice the value of the tilt angle A92.

Of course, the position of the angle sector 97 at the center of the slots 94, 95 is relative to the orientation of the rollers 53, 63 at 90 degrees.

According to the third embodiment, the pump 1 can also comprise a pressure sensor 100 located downstream from the two hydraulic outlet passages C1, C2 of the pistons 5, 6, To be able to measure the pressure at the outlet of the piston and to measure the pressure drop following the approach of one of the pistons to the point of reversal. The pressure sensor 100 included in the compensation means is connected to the control unit 10 or to the control unit 10 in the form of an electric signal SP and to the pressure sensor 10 as a function of the pressure value measured by the pressure sensor 10, And to any other means suitable for increasing the rotational speed. To this end, the triggering of the acceleration of the velocity of the drum 9 may be permitted by the value of the outlet pressure below a threshold equal to, for example, 15 bar.

According to one embodiment of the invention not shown, the pump 1 may comprise more than two pistons.

The above-described embodiments and alternative features may be combined to form a new embodiment of the invention.

Claims (10)

A pump (1) for supplying an application system of a liquid cover product,
And a motor (3) for operating at least two pistons (5, 6)
Characterized in that it comprises a drum (9) comprising an outer cylindrical surface (90) having a cam profile (92) rotated by the motor (3) And the roller connected to each of the pistons via one of the rods is fixed to the corresponding piston (5, 6) under the action of the rotation of the drum (9) And the other piston (5) is in contact with the cam profile at a position (A) offset at an angle relative to the position of the other rollers so that the other piston (5) Of one of the pistons (5), (6) when the piston (5, 6) reaches the point of reversal of its direction of movement Characterized in that it comprises a compensating means (97; 10; 100). The method according to claim 1,
Characterized in that the compensation means comprises means (10) for accelerating the rotational speed of the drum (9) for a predetermined length of time before and after passage of one of the pistons (5, 6) As shown in Fig. 3. The method of claim 2,
Characterized in that said acceleration means comprises a control unit (10) of said motor (3). 3. The method of claim 2,
Characterized in that the compensation means comprises a pressure sensor (100) arranged downstream from the pistons (5,6) and the acceleration means (10) Is adapted to increase the rotational speed (V) of said drum (9). The method according to claim 1,
The compensating means includes an inclination angle A97 with respect to a plane P2 perpendicular to the rotation axis X-X 'of the drum 9, which is larger than an inclination angle A92 of the remaining angle sector of the cam profile 92, ) Formed by two angular sectors (97) of said cam profile (92) having a predetermined angle. 6. The method of claim 5,
The inclination angle A97 of the angle sectors 97 of the cam profile 92 forming the compensation means is twice the inclination angle A92 of the remaining angle sector of the cam profile 92 Pump. The method according to claim 1,
Characterized in that it comprises two pistons (5, 6) offset at an angle of 90 [deg.]. The method according to claim 1,
The cam profile 92 comprises two helical slots 94 (each of which extends over half of the circumference of the drum 9) and which is symmetrical about a plane Pl passing through the axis of rotation X-X ' , 95). ≪ / RTI > The method according to claim 1,
Characterized in that the rollers (53, 63) are offset at an angle by an angle (A) comprised between 70 [deg.] And 100 [deg.]. The method according to claim 1,
Characterized in that the offset angle (A) of the rollers (53, 63) is 90 [deg.].

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