ES1257878U - Self-draining mop system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Self-draining mop system, characterized in that it comprises: a) a main body (1) of a self-draining mop, comprising: - a mast (2) provided with an internal conduit (21); - a cylindrical sleeve (3) arranged in a sliding manner around the mast (2) and connected to a smaller piston (31) that slides in a sealed manner along the internal conduit (21) of said mast (2); - An essentially cylindrical bushing (4) connected to a lower end of the mast (2) so that the internal conduit (21) of the mast (2) communicates, forming an internal watertight chamber, with an actuating conduit (41) of the sleeve (4) through which a larger piston (42) whose diameter is larger than the diameter of the smaller piston (4) slides in a sealed manner, where the larger piston (42) is connected to a return device that drives it up, where the larger piston (42) protrudes from the lower end of the bushing (4), and where the lower end of the bushing (4) further comprises a flange (43) projecting radially therefrom; and - two cams (44) connected to the flange (43) of the bushing (4) in a rotatable manner in diametrically opposite positions of said flange (43), where each cam (44) comprises a base rotatably connected to the flange (43) and provided with an actuation step (45), and elongated arms that protrude from the base, b) a self-draining mop head (6) attachable to a lower end of the larger plunger (42), where the head (6) has an essentially circular shape from whose periphery a vertical wall (61) protrudes, and where the edge The top of the vertical wall (61) comprises an interior horizontal flange (62) configured to engage the step (45) of actuation of the cams (555) when they are oriented with their arm in a vertical direction, and where the lower surface of the head (6) comprises a mop (63) formed by a plurality of absorbent strips, and c) a bucket (7) comprising a cylindrical or conical squeegee (71) provided with an inwardly projecting upper rim (72), so that, when the head (6) is coupled to the main body (1), the resulting self-wringing mop can alternate between: a rest position where the larger plunger (42) is in a retracted position, so that the head (6) connected to said larger plunger (42) is also in a retracted position where the inner horizontal flange (62) is hooked to the step (45) for actuation of the cams (44) which, in turn, are oriented with their elongated arm in an essentially vertical direction; and a draining position where a downward displacement of the cylindrical sleeve (3) along the mast (2) by a user causes the smaller plunger (31) to press a fluid present in the sealed internal chamber, which at in turn, it drives the larger piston (42) downwards which, in turn, causes a downward movement of the head (6) coupled thereto so that the inner horizontal flange (62) acts on the actuation step (45) to rotating the cams (44) until the elongated arms are arranged in an oblique direction, so that the elongated arms can engage the upper lip (72) present on the upper edge of the squeegee (71) and a further downward displacement of the liner (3) causes the larger plunger (42) to continue coming out and compress the mound (63) against the squeegee (71), characterized in that: The inner duct (21) of the mast (2) is divided into a central duct (21c) of circular shape and a peripheral duct (21p) of cylindrical shape, where the central duct (21c) is in communication with the drive duct (41) of the bushing (4) but the peripheral conduit (21p) is closed at its lower end, where the central conduit (21c) is in communication with the peripheral conduit (21p) through a slot (23) arranged in a portion bottom of said central duct (21c), and where the smaller plunger (31) is correspondingly divided into a central plunger (31c) of circular cross section that slides along the central duct (21c), and a peripheral plunger (31p) of cylindrical cross section that slides along the peripheral conduit (21p). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Self-draining mop system

OBJECT OF THE INVENTION

The present invention belongs to the field of utensils used for cleaning floors.

The object of the present invention is a new mop system that has a self-wringing mechanism designed to minimize the effort made by the user.

BACKGROUND OF THE INVENTION

The mop is still the most widely used utensil for cleaning floors. As is well known, a conventional mop is essentially made up of a pole at the lower end of which a head fitted with a plurality of strips made of an absorbent textile material is fixed. During use, the user holds the mop by the pole and rubs the textile strips on the head against the floor. Subsequently, the mocho is placed in a bucket with soap and water and drained with the help of a wringer attached to the bucket itself.

This type of universally known mop has a drawback related to the inconvenience of the mop wringing procedure. Indeed, to wring the mop out of the mop, it is necessary to insert the mop into the wringer and then apply considerable force in order to compress the absorbent strips that make up the mop and, in this way, expel the water from the mop. themselves.

To solve this problem, various draining systems and mechanisms have been designed which, in most cases, focus on the design of the drainer. By way of example, the following may be mentioned.

Spanish patent ES2380715 describes a mop that is made up of a plurality of strips configured to compress the mop of the mop when the user presses vertically down on the wringer.

The Spanish utility model U7801949 describes another wringer that is formed basically by a press mounted on a rolling structure that also allows to compress the mop of the mop.

The national patent ES2303391 describes a squeegee similar to that described in this document, but with the important difference in the way in which the cams are opened. This will be described in more detail later in this document.

Ultimately, none of these wringing systems have satisfactorily solved the problem, so there is still a need in the art for an improved wringing system.

DESCRIPTION OF THE INVENTION

The inventor of the present application provides a solution to this problem thanks to a new mop design that greatly facilitates the wringing procedure. In general, the new wringing system is based on the longitudinal displacement of the mop head relative to the pole to make it easier for the user to compress the mop attached to the head against the surface of the wringer. Simultaneously with the longitudinal movement of the mop head, the end of the mast has locking elements that prevent the mop head from leaving the wringer. This system, whose specific characteristics will be clear from the description in this document, reduces the effort required to wring the mop out of the mop.

In this document, references to the direction "up", "top", or the like, as well as "down", "bottom", or the like, are to be interpreted in relation to the natural position of the self-draining mop of the invention. . Therefore, the lower end of the self-draining mop will be the one where the head is located, and the upper end of the self-draining mop will be the one where the user holds or grasps it.

A first aspect of the present invention is directed to a self-draining mop system that mainly comprises three elements: a main body of a self-draining mop, a self-draining mop head, and a bucket equipped with a wringer with particular characteristics. Each of these items is described in more detail below.

a) Main body

The main body of the mop of the invention is basically formed by the following parts:

- Mast: This is a mast equipped with an internal conduit.

In principle, the internal conduit is a single cylindrical conduit that runs essentially throughout the mast from its gripping end to its lower end.

- Sleeve: This is a cylindrical sleeve arranged in a sliding manner around the mast and connected to a smaller piston that slides in a watertight manner along the internal conduit of said mast. Thus, when the user slides the cylindrical sleeve longitudinally along the mast, the smaller plunger moves longitudinally along the internal passage of the mast. To allow the connection between the liner, located outside the mast, and the plunger, located inside, the mast has a longitudinal slot that allows the passage of a connecting element between liner and smaller plunger.

Additionally, the main body of the self-wringing mop may comprise a retainer that allows the user to selectively lock the cylindrical sleeve in its retracted position. This would make it possible to override the self-draining mechanism that is described in the present invention depending on the user's needs.

Also, sometimes the great length of the shorter plunger causes buckling to appear. This is detrimental to the operation of the invention due to wear of the sealing element located at the lower end of the smaller plunger, for example an O-ring. To overcome this problem, a guide can be arranged along the path of the smaller plunger to prevent sagging.

- Bushing: It is an essentially cylindrical bushing connected to a lower end of the mast so that the internal conduit of the mast communicates, forming an internal watertight chamber, with a conduit of bushing drive. According to a preferred embodiment of the invention, the fluid in the sealed internal chamber is chosen from: water, glycol, glycerin, and air.

In turn, a larger piston, the diameter of which is greater than the diameter of the smaller piston, slides tightly inside the longitudinal drive conduit of the bushing. Also, the larger plunger protrudes from the lower end of the bushing. The difference in diameter between the smaller and larger pistons allows the effort that the user must make to move the sleeve, and therefore also the smaller piston, to be less in relation to what it would take to move the larger piston directly. In addition, it makes it possible to transform the smaller piston stroke into a shorter larger piston stroke.

In accordance with a preferred embodiment of the invention, the ratio of the smaller plunger cross section to the larger plunger cross section is approximately 1:10.

The larger plunger is connected to a return device that urges it upward so that when no force is exerted on the sleeve, the sleeve is in a retracted position near the grip end of the mast. In principle, the return device can be designed in different ways, although according to a particularly preferred embodiment of the invention the return device is a rubber or a spring connected to the larger piston.

Additionally, the lower end of the bushing comprises a lip projecting radially therefrom. For example, it may be a horizontal rim of essentially circular shape.

On the other hand, sometimes it may be necessary to provide the bushing with a small taper to allow it to be removed from the mold if it is manufactured by plastic injection. In that case, according to a preferred embodiment of the invention, an insert of variable thickness is added that lines the interior of the drive conduit of the bushing to recover its cylindrical shape. This variable thickness insert can be in principle of any material capable of carrying out the described function, such as a metal or a plastic material. Thus, by ensuring that the drive conduit is perfectly cylindrical, the sealing of the larger piston is ensured. In addition, this has the additional advantage that it allows a greater piston travel.

- Cams: These are two cams that are rotatably connected to the flange of the bushing in diametrically opposite positions of said flange. For this, each cam comprises a base rotatably connected to the flange which is provided with an actuation step, and elongated arms projecting from the base.

In addition, thanks to this operation it is possible to facilitate the replacement of the mop pad, as described in detail below.

b) Head

The self-wringing mop head attaches to a lower end of the larger plunger. This coupling can be done in any way as long as it allows the head to be uncoupled for replacement when it is excessively worn. For example, in a preferred embodiment of the invention, the lower end of the larger plunger may comprise a hole configured for snap engagement of a protrusion provided on the upper surface of the head.

Furthermore, in a particularly preferred embodiment of the invention, one of the head projection and the larger plunger hole has at least one pair of lugs or the like that prevent the mop head from rotating during use. relative to the larger plunger to which it is attached.

In addition, to ensure a more secure fixation between the head boss and the larger plunger hole, the head boss preferably has pressure anchors to the larger plunger hole to ensure a more secure fixation between both elements.

On the other hand, the head has an essentially circular shape from whose periphery a vertical wall protrudes, and in turn the upper edge of the vertical wall it comprises an internal horizontal rim configured to engage the actuation step of the cams when the latter are oriented with their arm in a vertical direction.

Furthermore, the lower surface of the head comprises a mop formed by a plurality of absorbent strips. These are strips of textile material similar to those used in any conventional mop.

c) Bucket

The bucket is of the conventionally used type, although it has the particularity that it comprises a cylindrical or conical squeegee equipped with an inwardly projecting upper lip. This upper rim may form a single piece with the squeegee, or a separate annular piece may be used which is attached, for example by pressure or by adhesives, to the upper edge of the squeegee.

Thanks to this configuration, when the head is attached to the main body, the resulting self-wringing mop can toggle between essentially two positions:

- Rest position

In the rest position, the larger plunger is in a retracted position, so that the head connected to said larger plunger is also in a retracted position. In this position, the inner horizontal rim of the head is hooked to the actuation step of the cams causing the latter, in turn, to be oriented with their elongated arm in an essentially vertical direction.

- Drain position

In the draining position, a downward displacement of the cylindrical sleeve along the mast by a user causes the smaller plunger to press a fluid present in the sealed internal chamber. The fluid, in turn, drives the larger plunger down which, in turn, causes a downward displacement of the head attached to it. In this way, the inner horizontal ridge acts on the actuation step to rotate the cams until the elongated arms are arranged in an oblique direction. In this oblique position, when the head is inside the squeegee, the elongated arms can be attached to the upper lip present on the upper edge of the squeegee. An additional downward movement of the liner causes the larger plunger to keep coming out and compressing the mop against the squeegee.

Therefore, this system reduces the effort that the user must make to compress the mop mop, since he only has to insert the mop head into the wringer and then move the shirt down. The difference in diameters between the smaller plunger and the larger plunger, as well as the coupling mechanism between the mop bushing and the rim of the wringer, mean that the compression force exerted on the mop is much greater than that applied by the user .

This application presents the important difference in relation to the patent of the prior art ES2303391 in the way in which the cams are opened. In document ES2303391, the opening of the cams occurs thanks to the contact of the larger piston against some projections thereof that occurs during the forward travel of said larger piston. This mode of operation had several shortcomings, which are solved by the cam opening mechanism described in this document.

Furthermore, according to a particularly preferred embodiment of the invention, the inner duct of the mast is divided into a central duct of circular shape and a peripheral duct of cylindrical shape, where the central duct is in communication with the drive duct of the bushing but the peripheral conduit is closed at its lower end. The central duct is in communication with the peripheral duct through a slot, that is, an essentially rectangular hole arranged in a lower portion of said central duct. Correspondingly, the smaller piston is correspondingly divided into a central piston of circular cross-section sliding along the central passage, and a peripheral piston of cylindrical cross-section sliding along the peripheral passage. In this way, all the fluid displaced by the peripheral plunger enters the central conduit through the socket, further increasing the pressure in the sealed internal chamber of the bushing. That is, this configuration increases the force transmitted by the smaller plunger to the larger plunger because it allows increasing the effective cross section of the main body of the self-wringing mop. Therefore, the effort that the user must make to wring the mop is reduced, and also a less travel of the shirt is achieved due to the displacement of a greater quantity of fluid.

On the other hand, it is generally known to use lubricants, usually lubricating oil, to facilitate the sliding of pistons and the like. However, in the present invention liquid petrolatum is preferably used as a lubricant to facilitate displacement of the minor and major plungers.

A second aspect of the present invention is also directed to a self-wringing mop main body as described above.

A third aspect of the present invention is also directed to a self-wringing mop head as described above.

A fourth aspect of the present invention is also directed to a self-wringing mop bucket as described above.

BRIEF DESCRIPTION OF THE FIGURES

Figs. 1a, 1b and 1c shows the main body of the self-wringing mop of the present invention respectively in the rest position and in the wringing position, and a detail of the shirt with the smaller plunger attached thereto.

Figs. 2a and 2b respectively show a view and a section of the self-wringing mop head according to the present invention.

Fig. 3 shows a view of a bucket provided with a self-draining mop wringer according to the present invention.

Figs. 4a and 4b show a self-draining mop formed by the main body coupled to the head respectively in the rest and wrung positions.

Figs. 5a-5c show in greater detail the interaction between the main body bushing and the head during the transition from the rest position to the wringing position.

Figs. 6a-6c schematically show the use of the self-wringing mop system of the present invention.

Figs. 7a and 7b show a longitudinal section of the self-draining mop respectively in the rest position and in the draining position.

Fig. 8 shows a detail of the main body of the writable mop where the internal duct of the mast is divided in two.

Fig. 9 shows a cross section of the smaller plunger of the mop main body shown in Fig. 8.

PREFERRED EMBODIMENT OF THE INVENTION

A particular example of a self-draining mop system according to the present invention is described below with reference to the attached figures.

Figs. 1a and 1b show a self-draining mop main body (1) comprising an elongated pole (2) along which a cylindrical sleeve (3) slides longitudinally. The cylindrical sleeve (3) is connected to a smaller plunger (31) that is housed in a watertight manner in an internal conduit (21) of the mast, so that when a user grasps the cylindrical sleeve (3) and moves it from its position retracted, closer to the grip end of the mast (2), to its forward position, closer to the end of the mast (2) where the head (6) is located, causes the smaller plunger (31) to move forward. The connection between the cylindrical sleeve (3) and the smaller piston (31) is implemented through a radial rib (32) that slides along a longitudinal slot (22) of the mast (2) when the cylindrical sleeve (3 ) moves longitudinally along said mast (2). This configuration is shown in greater detail in Fig. 1c, where the radial rib (32) that connects the cylindrical sleeve (3) with the smaller plunger (31) can be seen.

The lower end of the mast (2) is coupled to an essentially cylindrical bushing (4) and which has a cylindrical internal drive conduit (41) whose cross section is substantially greater than the cross section of the internal conduit (21). For example, the section ratio can be 10: 1. As can be seen in Figs. 7a and 7b, the internal conduit (21) of the mast (2) opens into the drive conduit (41) of the bushing (4), so that both together form a pressure chamber. A larger plunger (42) is watertightly housed within the inner conduit (21) so that it can slide down the length thereof when the user lowers the cylindrical sleeve (3). In addition, a return device, such as a spring (not shown in the figures), is attached to the larger piston (42) and to the interior of the pressure chamber so that exerts a constant force on said larger piston (42) that tends to move it towards its retracted position. Therefore, at times when the user does not exert any force on the cylindrical sleeve (3), the spring causes both the larger piston (42) and the smaller piston (31), and therefore also the cylindrical sleeve (3) ), move to their respective retracted positions.

The lower end of the bushing (4) has an essentially circular rim (43) to which two cams (44) are attached in diametrically opposite positions, each cam (44) having an elongated shape comprising a base attached to the rim (43) and a free arm. The attachment between the base of each cam (44) and the flange (43) is rotatable along an axis essentially tangent to the flange (43), so that the rotation of a cam causes the corresponding arm to move upwards. or down. Furthermore, the base of each cam (44) has an essentially flat-shaped step or tooth (45) which projects horizontally outward from the base of the cam (44) when the latter is oriented vertically.

Figs. 2a and 2b respectively show a side view and a longitudinal section of a self-wringing mop head (6) according to the present invention. As can be seen, the head (6) has an essentially circular plan shape and is provided with a vertical wall (61). In turn, the upper edge of the vertical wall (61) is provided with a horizontal rim (62) that projects inside said wall (61). The head (6) also has a projection (64) that protrudes in the center of its upper surface, and that is designed to engage a corresponding cavity arranged on the surface of the lower end of the larger plunger (4). The coupling between both pieces can be carried out, for example, by pressure, by thread, or in general in any way that allows the head (6) to be selectively coupled and uncoupled from the main body (1) of the self-draining mop.

The dimensions of the head (6) and the bushing (4) are designed so that, when the latter is coupled to the larger plunger (42) and the larger plunger (42) is in its retracted position, the horizontal flange (62) is coupled to the step (45) of the bushing (4) so that the arms of the cams (44) are in a vertical position. When the larger plunger (42) moves downward, the descent of the rim (62) of the head (6) causes a vertical force in a downward direction on the step (45) that causes the cam (44) to rotate outwards, accordingly. so that the arms of the cam (44) are opened to pass from the original vertical position to an oblique or inclined position relative to the longitudinal axis of the self-wringing mop.

Additionally, as is usual in any conventional mop head, the head (6) of the invention has a mop (63) fixed to its lower surface. The mop (63) is formed by a plurality of strips made of an absorbent textile material.

Fig. 3 shows a cross section of a bucket (7) provided with a wringer (71) particularly designed for use with the self-draining mop described. Specifically, the squeegee (71) is attached to the upper edge of the bucket (7) and has an essentially conical shape that tapers from top to bottom. This wringer (71) also has the particularity that it has a horizontal rim (72) that protrudes inwardly at its upper edge.

Figs. 4a and 4b show in a simplified way the operation of the self-wringing mop according to the present invention. In an initial state of rest, the cylindrical sleeve (3) is in its retracted position, which also causes the larger plunger (42) and the head (6) to be in the retracted position. The steps (45) of the cams (44) are coupled to the flange (62) of the vertical wall (61) of the head (6), and therefore the arms of the cams (44) are in a vertical position. When the user actuates the cylindrical sleeve (3) through its downward movement along the mast (2) of the main body (1) of the self-draining mop, the corresponding lowering of the smaller plunger (31) causes an increase pressure in the sealed pressure chamber and thus also causes the larger plunger (42) to lower along the drive conduit (41). The head (6), which is coupled to the lower end of the larger plunger (42), moves downwards relative to the bushing (4), and during this movement the interaction between the rim (62) of the head (6) and the Steps (45) of the cams (44) cause the cams (44) to rotate outward. In this way, the arms of the cams (44) are caused to move from the vertical position to an oblique or inclined position. This process is represented in more detail in Figs. 5a-5c and in Figs. 7a-7b. This mechanism contrasts with the one described in the prior art patent ES2303391, where the larger piston caused the cams to open.

This configuration presents an additional advantage consisting in that it facilitates the operation of disassembling the head (6) from the lower end of the larger piston (42). Indeed, if starting from the position shown in Fig. 7 in which the larger piston (42) is in its upper position, the user manually pulls the arms of the cams (44) downwards, the rotation of the cams (44) cause the respective steps (45) to exert a vertical downward force on the vertical wall (61) of the head. This force extracts the projection (64) from the corresponding cavity of the larger plunger (42), so that the head (6) is separated from said larger plunger (42).

Figs. 6a-6c show how the self-draining mop formed by the combination of the main body (1) and the head (6), by operating in the manner described in the previous paragraph, facilitates the wringing operation for the user. First, with the self-wringing mop in its resting position, the user uses the mop in the conventional way to absorb a liquid present on the floor. Next, as shown in Fig. 6a, the user inserts the lower end of the main body (1) to which the head (6) is fixed in the squeegee (71). Once inside, the user manually lowers the cylindrical sleeve (3). This descent causes the larger plunger (42), and correspondingly the head attached to it, to move downward. This displacement, as described above, causes the cams (44) to rotate outward. When the arms of the cams (44) open, they engage or rest against the horizontal edge (72) of the squeegee (71), so that the bushing (4) as a whole is supported below against said horizontal edge (72) . If the user continues to move the cylindrical sleeve (3) downward, the larger plunger (42) also moves downward and causes the mop (63) that protrudes below the head (6) to compress against the bottom of the squeegee (71 ). Compression does not require the application of a great force by the user, since the bush (4) is firmly supported against the rim (72) of the squeegee (71).

Fig. 8 shows a particularly preferred embodiment of the mast (2) where the smaller piston (31) is divided into a central piston (31c) of circular cross section and a peripheral piston (31p) of cylindrical cross section. Fig. 9 shows a cross section of the plunger (31) where the shape of the central plunger (31c) and the peripheral plunger (31p) is more clearly seen. Correspondingly, the internal conduit (21) of the mast divided into a central conduit (21c) of circular shape through which the central plunger (31c) slides and a peripheral conduit (21p) of cylindrical form through which the peripheral plunger (31p slides ). The peripheral duct (21p) is closed at the bottom, and communicates with the central duct (21c) through a slot (23) or rectangular hole made in a lower portion of the wall that delimits the central duct (21c). Thus, when the smaller plunger (31) is moved longitudinally downward, it displaces fluid both along the central conduit (21c) and the peripheral conduit (21p). The fluid displaced along the peripheral conduit (21p) enters the final section of the central conduit (21c) through the slot (23), further increasing the pressure increase generated in the drive conduit (41). This makes it possible to reduce the force that the user has to exert on the shirt (3) when carries out the wringing operation.

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Claims (20)

1. Self-draining mop system, characterized in that it comprises: a) a main body (1) of a self-draining mop, comprising: - a mast (2) provided with an internal conduit (21); - a cylindrical sleeve (3) arranged in a sliding manner around the mast (2) and connected to a smaller piston (31) that slides in a sealed manner along the internal conduit (21) of said mast (2); - an essentially cylindrical bushing (4) connected to a lower end of the mast (2) so that the internal conduit (21) of the mast (2) communicates, forming a sealed internal chamber, with an actuating conduit (41) of the sleeve (4) through which a larger piston (42) whose diameter is larger than the diameter of the smaller piston (4) slides in a sealed manner, where the larger piston (42) is connected to a return device that drives it up , where the larger piston (42) protrudes from the lower end of the bushing (4), and where the lower end of the bushing (4) further comprises a flange (43) that projects radially therefrom; and - two cams (44) connected to the flange (43) of the bushing (4) in a rotary manner in diametrically opposite positions of said flange (43), where each cam (44) comprises a base rotatably connected to the flange (43) and provided with an actuation step (45), and elongated arms that protrude from the base, b) a self-draining mop head (6) attachable to a lower end of the larger plunger (42), where the head (6) has an essentially circular shape from whose periphery a vertical wall (61) protrudes, and where the edge The top of the vertical wall (61) comprises an internal horizontal flange (62) configured to engage the step (45) of actuation of the cams (555) when they are oriented with their arm in a vertical direction, and where the lower surface of the head (6) comprises a mop (63) formed by a plurality of absorbent strips, and c) a bucket (7) comprising a cylindrical or conical squeegee (71) provided with an inwardly projecting upper rim (72), so that, when the head (6) is coupled to the main body (1), the resulting self-wringing mop can alternate between: a rest position where the larger plunger (42) is in a retracted position, such that the head (6) connected to said larger plunger (42) is also in a retracted position where the inner horizontal flange (62) is hooked to the step (45) of action of the cams (44) which, in turn, are oriented with their elongated arm in an essentially vertical direction; and a draining position where a downward displacement of the cylindrical sleeve (3) along the mast (2) by a user causes the smaller plunger (31) to press a fluid present in the sealed internal chamber, which at in turn, it drives the larger plunger (42) downwards which, in turn, causes a downward movement of the head (6) coupled thereto so that the inner horizontal flange (62) acts on the actuation step (45) to rotating the cams (44) until the elongated arms are arranged in an oblique direction, so that the elongated arms can engage the upper flange (72) present on the upper edge of the squeegee (71) and a further downward movement of the liner (3) causes the larger plunger (42) to continue to come out and compress the mound (63) against the squeegee (71), characterized by that: The inner duct (21) of the mast (2) is divided into a central duct (21c) of circular shape and a peripheral duct (21p) of cylindrical shape, where the central duct (21c) is in communication with the drive duct ( 41) of the bushing (4) but the peripheral conduit (21p) is closed at its lower end, where the central conduit (21c) is in communication with the peripheral conduit (21p) through a slot (23) arranged in a portion bottom of said central conduit (21c), and where the smaller plunger (31) is correspondingly divided into a central plunger (31c) of circular cross section that slides along the central conduit (21c), and a peripheral plunger (31p) of cylindrical cross section that slides along the peripheral conduit (21p). 2. Self-wringing mop system according to claim 1, wherein the ratio between the cross section of the smaller plunger (31) and the cross section of the larger plunger (42) is approximately 1:10. 3. Self-draining mop system according to any of the preceding claims, wherein the fluid in the sealed internal chamber is chosen from: water, glycol, glycerin, and air. 4. Self-draining mop system according to any of the preceding claims, wherein the return device is a rubber or a spring connected to the larger plunger (42). 5. Self-draining mop system according to any of the claims above, where the lower end of the larger plunger (42) comprises a hole configured for pressure engagement of a projection (64) arranged on the upper surface of the head (6). 6. Self-draining mop system according to claim 5, wherein one of the projection (64) of the head (6) and the hole of the larger plunger (42) has at least one pair of lugs or the like that prevent it from During use, the mop head (6) can rotate relative to the larger plunger (42) to which it is attached. 7. Self-draining mop system according to any of claims 5-6, where the projection (64) of the head (6) has pressure anchors to the hole of the larger plunger (42) to ensure a more secure fixation between both elements. 8. Self-draining mop system according to any of the preceding claims, wherein the internal duct (21) of the mast (2) is divided into a central duct (21c) of circular shape and a peripheral duct (21p) of circular shape cylindrical, and the smaller plunger (31) is correspondingly divided into a central plunger (31c) of circular cross section that slides along the central passage (21c), and a peripheral plunger (31p) of cylindrical cross section that slides along length of the peripheral duct (21p). 9. Self-draining mop system according to any of the preceding claims, further comprising a retainer that allows the user to selectively lock the cylindrical sleeve (3) in its retracted position. 10. Self-wringing mop system according to any of the preceding claims which, in the event that the drive duct (41) of the bushing (4) has a slight taper to facilitate removal from the mold, it also comprises an insert of variable thickness that lines the interior of the drive conduit (41) to regain its cylindrical shape. 11. Self-draining mop system according to any of the preceding claims, where liquid petroleum jelly is used as a lubricant to facilitate the movement of the smaller (31) and larger (42) plungers. 12. Main body (1) of self-draining mop, characterized in that it comprises: - a mast (2) provided with an internal conduit (21); - a cylindrical sleeve (3) arranged in a sliding manner around the mast (2) and connected to a smaller piston (31) that slides in a sealed manner along the internal conduit (21) of said mast (2); - An essentially cylindrical bushing (4) connected to a lower end of the mast (2) so that the internal conduit (21) of the mast (2) communicates, forming a sealed internal chamber, with an actuating conduit (41) of the sleeve (4) through which a larger piston (42) whose diameter is larger than the diameter of the smaller piston (4) slides in a sealed manner, where the larger piston (42) is connected to a return device that drives it up , where the larger piston (42) protrudes from the lower end of the bushing (4), and where the lower end of the bushing (4) further comprises a flange (43) that projects radially therefrom; and - two cams (44) connected to the flange (43) of the bushing (4) in a rotary manner in diametrically opposite positions of said flange (43), where each cam (44) comprises a base rotatably connected to the flange (43) and provided with an actuation step (45), and elongated arms that protrude from the base, characterized in that The inner duct (21) of the mast (2) is divided into a central duct (21c) of circular shape and a peripheral duct (21p) of cylindrical shape, where the central duct (21c) is in communication with the drive duct ( 41) of the bushing (4) but the peripheral conduit (21p) is closed at its lower end, where the central conduit (21c) is in communication with the peripheral conduit (21p) through a slot (23) arranged in a portion bottom of said central conduit (21c), and where the smaller plunger (31) is correspondingly divided into a central plunger (31c) of circular cross section that slides along the central conduit (21c), and a peripheral plunger (31p) of cylindrical cross section that slides along the peripheral conduit (21p). 13. Main body (1) of a self-wringing mop according to claim 12, which, in the event that the drive duct (41) of the bushing (4) has a slight taper to facilitate demoulding, also comprises an insert of variable thickness that covers the inside of the drive conduit (41) to regain its cylindrical shape. 14. Self-wringing mop main body (1) according to any one of claims 12-13, wherein the ratio between the cross section of the smaller plunger (31) and the cross section of the larger plunger (42) is approximately 1 : 10. 15. Main body (1) of a self-draining mop according to any of claims 12-14, wherein the fluid in the sealed internal chamber is chosen from: water, glycol, glycerin, and air. 16. Self-draining mop main body (1) according to any of claims 12-15, wherein the return device is a rubber or a spring connected to the larger plunger (42). 17. Main body (1) of a self-wringing mop according to any of claims 12-16, wherein the lower end of the larger plunger (42) comprises an orifice configured for the snap engagement of a projection (64) arranged in the upper surface of the head (6). 18. Self-wringing mop main body (1) according to any of claims 12-17, further comprising a retainer that allows the user to selectively lock the cylindrical sleeve (3) in its retracted position. 19. Self-wringing mop head (6) attachable to the lower end of the larger plunger (42) of the main body (1) according to claim 12, wherein the head (6) has an essentially circular shape from whose periphery a vertical wall projects (61), and where the upper edge of the vertical wall (61) comprises an inner horizontal flange (62) configured to engage the step (45) of actuation of the cams (44) when they are oriented with their arm in a vertical direction , and where the lower surface of the head (6) comprises a mop (63) formed by a plurality of absorbent strips, so that, when the head (6) is coupled to the main body (1), the resulting self-wringing mop can alternate between: a rest position where the larger plunger (42) is in a retracted position, such that the head (6) connected to said larger plunger (42) is also in a retracted position where the inner horizontal flange (62) is hooked to the step (45) for actuation of the cams (44) which, in turn, are oriented with their elongated arm in an essentially vertical direction; and a draining position where a downward displacement of the cylindrical sleeve (3) along the mast (2) by a user causes the smaller plunger (31) to press a fluid present in the sealed internal chamber, which at in turn, it drives the larger plunger (42) downwards which, in turn, causes a downward movement of the head (6) coupled thereto so that the inner horizontal flange (62) acts on the actuation step (45) to rotating the cams (44) until the elongated arms are arranged in an oblique direction, so that the elongated arms can engage the upper lip (72) present on the upper edge of the squeegee (71) and further displacement towards down the liner (3) causes the larger plunger (42) to continue to come out and compress the mop (63) against the squeegee (71). 20. Bucket (7) comprising a cylindrical or conical wringer (71) provided with an upper rim (72) that protrudes inwardly so that, when the cams (44) of a mop formed by the main body (1) according to claim 12 coupled to a head (6) according to claim 19 are oriented with their arms in an oblique direction, said arms rest on the lower surface of said upper rim (72), preventing the mop from being extracted from inside the wringer (71).