JP2009028691A - Mat washing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mat washing apparatus capable of carrying out brushing at the tip end part of a brush even in the case where a mat with a large thickness size is inserted and carrying out normal brushing with a small torque. <P>SOLUTION: An upper feeding roller 3 is installed above a lower feeding roller 1 and a rotary brush 2 arranged adjacently and in parallel each other. The mat washing apparatus is configured in a manner that a mat can be inserted and passed between the lower feeding roller 1 and the upper feeding roller 3 and between the rotary brush 2 and the upper feeding roller 3. The washing apparatus is provided with a slide mechanism S which slides the upper feeding roller 3 in the sliding directions E and E' to make the gap size between the rotary brush 2 and the upper feeding roller 3 changed to be large or small corresponding to the large or small change when the gap size between the lower feeding roller 1 and the upper feeding roller 3 is changed to be large or small. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a mat cleaner.

  Some conventional mat cleaning machines include a pair of upper and lower brushes for cleaning a mat (see, for example, Patent Document 1).

However, the distance between the upper brush and the lower brush is constant, and when a mat with a large thickness is inserted between the upper and lower brushes, a large torque is applied to bend to the base of the brush, resulting in insufficient cleaning. At the same time, the motor and brushes were consumed quickly. Further, when a mat having a particularly large thickness is inserted, there is a disadvantage that it often cannot be restarted when the motor is stopped during cleaning, and it takes a long time to take out the mat.
JP 2003-190897 A

  The problem to be solved is that when a mat with a large thickness is inserted, a large torque is applied to bend to the base of the brush, cleaning becomes insufficient, and the motor and brush are consumed quickly. . Further, when the motor is stopped during cleaning, particularly when a mat having a large thickness is inserted, it is often impossible to restart, and it takes a lot of time to take out the mat. That is, it is not possible to perform appropriate cleaning according to the thickness dimension of the mat.

  Accordingly, the mat cleaning machine according to the present invention includes an upper feed roller disposed above the lower feed roller and the rotary brush arranged in parallel with each other, and the rotary brush between the lower feed roller and the upper feed roller. When the gap between the lower feed roller and the upper feed roller changes in size, the gap between the rotary brush and the upper feed roller corresponds to the above size. A slide mechanism is provided in which the upper feed roller slides in a sliding direction that changes in size.

When the contact between the lower feed roller and the upper feed roller is A and the contact between the rotary brush and the upper feed roller is B, the slide mechanism causes the rotation axis of the upper feed roller to be the contact A. And the vertical segment of the line segment connecting the contact B is moved.
The slide mechanism includes a linear guide mechanism that guides the upper feed roller so as to be linearly slidable in the slide direction. Further, the upper feed roller is elastically moved in the slide direction approaching the lower feed roller and the rotating brush. A pressing mechanism for energizing is provided.

  According to the mat cleaning machine of the present invention, even when a mat having a large thickness is inserted, normal brushing can be performed with a small torque by brushing at the tip of the brush. And durability of a motor or a brush can be improved and an electric consumption can be suppressed. Furthermore, even if the motor is stopped during cleaning, it is possible to easily restart even when a mat with a large thickness is inserted by reducing the burden on the brush during restarting. It is possible to eliminate wasted time for taking out.

  FIG. 1 and FIG. 2 show an embodiment of the present invention, and this mat cleaning machine is located above a lower feed roller 1 and a rotating brush 2 (including an obliquely upper part) arranged close to each other. An upper feed roller 3 is disposed, and a mat M (for example, an entrance mat, or the like) is sequentially placed between the lower feed roller 1 and the upper feed roller 3 and between the rotary brush 2 and the upper feed roller 3 as indicated by an arrow P. A mat with a pile ground laid at the foot of an automobile) can be inserted. A brush 20 is planted on the rotating brush 2, and dirt, dust, dust, etc. adhering to the mat M are wiped off by the brush 20 (the tip 20 a thereof). Reference numeral 4 denotes an upper sponge roller. Reference numeral 5 denotes a lower sponge roller. The mat M is cleaned while being inserted between the lower feed roller 1 and the upper feed roller 3, between the rotating brush 2 and the upper feed roller 3, and between the upper sponge roller 4 and the lower sponge roller 5. The

When the gap dimension H ₁ between the lower feed roller 1 and the upper feed roller 3 changes in size, the slide directions E and E ′ such that the gap dimension H ₂ between the rotating brush 2 and the upper feed roller 3 changes in size corresponding to the above magnitude. The upper feed roller 3 includes a slide mechanism S that slides (reversibly). That is, the sliding direction E indicates the direction in which the gap dimension H ₁ and gap dimension H ₂ is increased. The slide direction E ′ indicates a direction in which the gap dimension H ₁ and the gap dimension H ₂ are reduced (the direction opposite to the slide direction E).

  Specifically, as shown in FIG. 3, when the contact between the lower feed roller 1 and the upper feed roller 3 is A and the contact between the rotating brush 2 and the upper feed roller 3 is B, the slide mechanism S (FIG. 1). The rotation axis X of the upper feed roller 3 is configured to reciprocate along a perpendicular bisector N of a segment R connecting the contact A and the contact B.

  Next, referring back to FIG. 1, the slide mechanism S includes a linear guide mechanism J that guides the upper feed roller 3 so as to be slidable linearly reciprocally (slidably linearly) in the slide direction E.

  Specifically, the linear guide mechanism J is configured as follows. A sliding bearing case 7 having guide grooves 6 and 6 in a direction parallel to the vertical bisector N (see FIG. 3) is attached to the washing machine body 8. A bearing 9 that pivotally supports the upper feed roller 3 is attached to a washing machine body 8 via a slide type bearing case 7.

  The mat cleaning machine includes a pressing mechanism K that elastically urges the upper feed roller 3 in the slide direction E ′ approaching the lower feed roller 1 and the rotating brush 2 (results). Specifically, the pressing mechanism K is configured as follows. A pressing member 10 is provided that presses the bearing 9 while swinging in the sliding direction E ′ along the guide groove 6 of the bearing case 7. A base end portion 11 of the pressing member 10 is pivotally attached to the cleaning machine main body 8 with a pivot shaft 12, and a distal end portion 13 is connected to one end 15 of an elastic member (for example, a tension spring) 14 so that the sliding direction E The outer ring 9a of the bearing 9 is elastically biased. A pressing force F (see FIG. 2) acts on the mat M from the upper feed roller 3 by the pressing mechanism K.

Next, the movement of the upper feed roller 3 when the thickness dimension T (see FIG. 2) of the mat M is large or small will be described with reference to FIG. When the mat M having a small thickness T is inserted between the lower feed roller 1 and the upper feed roller 3 by the slide mechanism S (see FIG. 1), the upper feed roller 3 slides in the slide direction E, The rotational axis X of the upper feed roller 3 moves to a position Y away from the rotary brush 2 on the vertical bisector N. If the gap dimension between the lower feed roller 1 and the upper feed roller 3 at this time is G ₁ and the gap dimension between the rotary brush 2 and the upper feed roller 3 is G ₂ , the gap dimension G ₁ and the gap dimension G ₂ are substantially equal. .

When the mat M having a large thickness T is inserted between the lower feed roller 1 and the upper feed roller 3, the upper feed roller 3 slides in the sliding direction E, and the rotation axis X of the upper feed roller 3 is vertical. It moves on the bisector N to a position Z further away from the rotary brush 2 than the position Y. If the gap dimension between the lower feed roller 1 and the upper feed roller 3 at this time is G ₁ ′ and the gap dimension between the rotating brush 2 and the upper feed roller 3 is G ₂ ′, the gap dimension is G ₁ ′ and the gap dimension. G ₂ 'is substantially equal. That is, regardless of the thickness dimension T of the mat M (corresponding to the thickness dimension T of the mat M), the gap dimension H ₁ between the lower feed roller 1 and the upper feed roller 3, the rotating brush 2 and the upper feed roller 3. gap dimension H ₂ is equal to approximately the.

  Returning to FIG. 1, the upper sponge roller 4 is configured to be close to and away from the lower sponge roller 5. Specifically, the upper sponge roller 4 is attached to a swing plate member 18 that can swing around the rotation shaft 17. A sponge roller elastic member (for example, a tension spring) 19 elastically urges the swing plate member 18 in the direction Q approaching the lower sponge roller 5.

In the present invention, the design can be changed. For example, the slide direction E is preferably an arcuate curve in which the gap dimension H ₁ and the gap dimension H ₂ are always equal. That is, the slide mechanism S includes a curved guide mechanism (not shown). The configuration of the rollers other than the lower feed roller 1, the rotating brush 2, and the upper feed roller 3 can be freely changed. For example, the upper sponge roller 4 and the lower sponge roller 5 can be omitted or other rollers can be added. Also good.

As described above, according to the present invention, the upper feed roller 3 is disposed above the lower feed roller 1 and the rotating brush 2 that are arranged close to each other and rotate between the lower feed roller 1 and the upper feed roller 3. The mat M can be inserted between the brush 2 and the upper feed roller 3 in order, and when the gap dimension H ₁ between the lower feed roller 1 and the upper feed roller 3 changes in size, the gap between the rotating brush 2 and the upper feed roller 3 is changed. sliding direction E as dimension H ₂ changes the magnitude in response to the magnitude, since the upper feed roller 3 provided with a slide mechanism S to slide E ', if it is inserted the thickness T is large mat M However, it is possible to perform normal brushing with a small torque by brushing with the tip 20a of the brush 20. And durability of a motor and the brush 20 can be improved, and an electric consumption can be suppressed.

  Furthermore, even if the motor is stopped during cleaning, it is possible to easily restart even when the mat M having a large thickness dimension T is inserted by reducing the burden on the brush 20 at the time of restarting. In this case, useless time for taking out the mat M can be eliminated.

Further, when the contact point between the lower feed roller 1 and the upper feed roller 3 is A and the contact point between the rotary brush 2 and the upper feed roller 3 is B, the slide mechanism S causes the rotation axis X of the upper feed roller 3 to be a contact point. Since it is configured to move on the vertical bisector N of the line segment R connecting A and the contact point B, the gap dimension between the lower feed roller 1 and the upper feed roller 3 regardless of the thickness dimension T of the mat M. H ₁ and the gap dimension H ₂ between the rotating brush 2 and the upper feed roller 3 can be made approximately equal, and the force (pressing force F) by which the upper feed roller 3 presses the mat M can be made substantially constant. it can.

  The slide mechanism S includes a linear guide mechanism J that guides the upper feed roller 3 linearly in the slide direction E, and further slides the upper feed roller 3 closer to the lower feed roller 1 and the rotating brush 2. Since the holding mechanism K for elastically urging and energizing in the direction E ′ is provided, it can be manufactured easily and at a lower cost than the one having the curved guide mechanism, and the upper feed roller 3 is used for the mat M. The feed can be reliably applied and the rotary brush 2 can be appropriately cleaned.

It is a side perspective view showing one embodiment of the present invention. It is a principal part expansion simplified figure which shows a use condition. It is explanatory drawing. It is explanatory drawing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Lower feed roller 2 Rotating brush 3 Upper feed roller A Contact B Contact E Slide direction E 'Slide direction H ₁ Clearance dimension H ₂ Clearance dimension J Linear guide mechanism K Holding mechanism M Matt N Vertical bisection line R Line segment S Slide Mechanism X Center of rotation

Claims (3)

An upper feed roller (3) is disposed above the lower feed roller (1) and the rotating brush (2) that are arranged close to each other and between the lower feed roller (1) and the upper feed roller (3). The mat (M) can be inserted between the rotary brush (2) and the upper feed roller (3) in order, and the gap dimension (H ₁ ) between the lower feed roller (1) and the upper feed roller (3). ) Changes in size, the clearance dimension (H ₂ ) between the rotating brush (2) and the upper feed roller (3) changes in the sliding direction (E) (E ′) so that the size changes corresponding to the size. A mat cleaning machine comprising a slide mechanism (S) for sliding the feed roller (3).   When the contact between the lower feed roller (1) and the upper feed roller (3) is (A) and the contact between the rotating brush (2) and the upper feed roller (3) is (B), the slide By the mechanism (S), the rotational axis (X) of the upper feed roller (3) is on the perpendicular bisector (N) of the line (R) connecting the contact (A) and the contact (B). The mat washing machine according to claim 1, wherein the mat washing machine is configured to move.   The slide mechanism (S) includes a linear guide mechanism (J) that guides the upper feed roller (3) in a linearly slidable manner in the slide direction (E). The mat washing machine according to claim 1 or 2, further comprising a pressing mechanism (K) for elastically energizing in a sliding direction (E ') approaching the lower feed roller (1) and the rotating brush (2).

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