Patent Description:
<CIT> discloses a paper feeding device that has at least a paper placing table which includes a positioning guide in all directions, a sticking mechanism which includes a sticking head, and an air supply mechanism, that makes a first layer paper stick to the sticking head of the sticking mechanism one by one in turn among a plurality of sheets of stacked paper in a state of being positioned on the paper placing table at a predetermined position by the positioning guide while the air supply mechanism sends air between a second layer paper thereunder and the first layer paper, and that sucks the first layer paper to be let out to a downstream process. In the paper feeding device, the sticking mechanism includes a blasting device that blasts an air flow downward to hit or to sweep over a forward portion thereof from edges on a front side and/or a lateral side thereof to the edges of the front side and/or the lateral side during an operation of the sticking mechanism in a case of letting out the first layer paper on the stacked paper and that keeps a blasting condition of the air flow constant on the line of flow of the sticking mechanism. <CIT>, disclosing the preamble of claims <NUM> and <NUM>, relates to a recording-material-transporting device including an attracting part to which a recording material is attracted from below, and a blowing device that blows air from a position higher than the attracting part to an edge of the recording material attracted to the attracting part.

An object of the present disclosure is to supply air, in a configuration where a floating medium is stuck and fed, to a front surface side of a second medium positioned immediately below a stuck first medium in a horizontal direction from a downstream side to an upstream side in a medium feeding direction and to prevent double-feeding of media compared to a configuration where the second medium is separated from the first medium.

According to a first aspect of the present disclosure, there is provided a feeding device including a supply unit that supplies air between a plurality of stacked media and that floats the media, a feeding unit that makes the media floated by the supply unit stick thereto and that feeds the media, a separating unit that supplies the air obliquely downward to a front surface side of a second medium positioned immediately below a first medium stuck to the feeding unit from a downstream side to an upstream side in a medium feeding direction and that separates the second medium from the first medium, and a blasting unit that blasts the air obliquely downward to the front surface side of the second medium from the downstream side to the upstream side in the medium feeding direction and that has a blasting angle of the air with respect to the medium feeding direction larger than a supply angle of the air of the separating unit.

According to a second aspect of the present disclosure, there is provided a feeding device including a supply unit that supplies air between a plurality of stacked media and that floats the media, a feeding unit that makes the media floated by the supply unit stick thereto and that feeds the media, a separating unit that supplies the air obliquely downward to a front surface side of a second medium positioned immediately below a first medium stuck to the feeding unit from a downstream side to an upstream side in a medium feeding direction and that separates the second medium from the first medium, and a blasting unit that is a separate body from the separating unit, that blasts the air obliquely downward to the front surface side of the second medium from the downstream side to the upstream side in the medium feeding direction, and that has a pressure applied to the second medium through air blasting higher than a pressure applied to the second medium through air supply by the separating unit.

According to a third aspect of the present disclosure, there is provided the feeding device according to the second aspect, in which an air blasting region with respect to the second medium caused by the blasting unit may be narrower than an air supply region with respect to the second medium caused by the separating unit.

According to a fourth aspect of the present disclosure, there is provided the feeding device according to any one of the first aspect to the third aspect, in which the feeding unit may deliver the medium to a feeding section through a movement in the medium feeding direction with respect to a device body, and the blasting unit may be fixed to the device body.

According to a fifth aspect of the present disclosure, there is provided the feeding device according to the fourth aspect, in which the feeding unit may have a sticking surface to which the first medium is stuck, and an air supply port of the separating unit and an air blasting port of the blasting unit may be positioned on a downstream side of the sticking surface in the medium feeding direction and on an inner side in a width direction of the medium in plan view.

According to a sixth aspect of the present disclosure, there is provided the feeding device according to the fourth aspect or the fifth aspect, in which an air supply port of the separating unit and an air blasting port of the blasting unit may be shifted away from each other in a direction orthogonal to the medium feeding direction in plan view.

According to a seventh aspect of the present disclosure, there is provided the feeding device according to the sixth aspect, in which air supply ports may be disposed at an interval in the orthogonal direction in plan view, and the air blasting port may be disposed between the air supply ports adjacent to each other in the orthogonal direction.

According to an eighth aspect of the present disclosure, there is provided the feeding device according to any one of the first aspect to the fifth aspect, in which the separating unit may have an air supply unit disposed below the blasting unit, an air supply path that leads air supplied from the air supply unit upward, and a guide unit that guides the air supplied from the air supply path obliquely downward from the downstream side to the upstream side in the medium feeding direction.

According to a ninth aspect of the present disclosure, there is provided the feeding device according to the eighth aspect, in which the guide unit and an air blasting port of the blasting unit may be shifted away from each other in a direction orthogonal to the medium feeding direction in plan view.

According to a tenth aspect of the present disclosure, there is provided the feeding device according to the eighth aspect or the ninth aspect, in which the feeding unit may have a sticking surface to which the first medium is stuck and an overhanging portion that overhangs toward the downstream side in the medium feeding direction, the sticking surface of the feeding unit and a lower surface of the overhanging portion may be connected to each other in the medium feeding direction, and the guide unit may be provided at the lower surface of the overhanging portion.

According to an eleventh aspect of the present disclosure, there is provided the feeding device according to any one of the first aspect to the tenth aspect, in which the blasting unit may blast the air for a period from air supply start from at least the separating unit to the second medium to feeding start of the first medium by the feeding unit.

According to a twelfth aspect of the present disclosure, there is provided the feeding device according to the eleventh aspect, in which the blasting unit may continuously blast the air until a feeding job of the plurality of media ends.

According to a thirteenth aspect of the present disclosure, there is provided the feeding device according to the twelfth aspect, in which an air blasting force of the blasting unit may be smaller than a medium sticking force of the feeding unit.

According to a fourteenth aspect of the present disclosure, there is provided the feeding device according to any one of the first aspect to the tenth aspect, in which the blasting unit may blast the air to the second medium after the air is started to be supplied from the separating unit to the second medium.

According to a fifteenth aspect of the present disclosure, there is provided the feeding device according to the fourteenth aspect, in which the blasting unit may stop blasting of the air to the second medium before feeding start of the first medium by the feeding unit.

In the feeding device of the first aspect, in a configuration where the floating medium is stuck and fed, air is supplied to the front surface side of the second medium positioned immediately below the stuck first medium in a horizontal direction from the downstream side to the upstream side in the medium feeding direction, and the double-feeding of the media can be prevented compared to a configuration where the second medium is separated from the first medium.

In the feeding device of the second aspect, in a configuration where the floating medium is stuck and fed, air is supplied to the front surface side of the second medium positioned immediately below the stuck first medium in a horizontal direction from the downstream side to the upstream side in the medium feeding direction, and the double-feeding of the media can be prevented compared to a configuration where the second medium is separated from the first medium.

In the feeding device of the third aspect, compared to a configuration where the air blasting region is larger than the air supply region, a generation amount of the blasted air caused by the blasting unit can be reduced.

In the feeding device of the fourth aspect, a failure of delivery of a downstream end of the first medium in the medium feeding direction to the feeding section can be prevented compared to a configuration where the blasting unit moves together with the feeding unit.

In the feeding device of the fifth aspect, compared to a configuration where the air supply port of the separating unit and the air blasting port of blasting unit are positioned on the downstream side of the sticking surface in the feeding direction and on the outer side in the width direction of the medium in plan view, a failure of delivery of the downstream end of the first medium stuck to the feeding unit in the medium feeding direction to the feeding section can be prevented.

In the feeding device of the sixth aspect, compared to a configuration where the air supply port of the separating unit and the air blasting port of the blasting unit are at the same position in the direction orthogonal to the medium feeding direction in plan view, air supply from the air supply port and air blasting from the air blasting port can be simultaneously performed.

In the feeding device of the seventh aspect, compared to a configuration where the air blasting port is disposed on the outer side of the air supply ports adjacent to each other in the direction orthogonal to the medium feeding direction in plan view, air can be easily blasted to the front surface side of the second medium.

In the feeding device of the eighth aspect, compared to a configuration where the air supply unit of the separating unit is disposed on the same side as the blasting unit, a degree of freedom of layout improves.

In the feeding device of the ninth aspect, compared to a configuration where the guide unit of the separating unit and the air blasting port of the blasting unit are at the same position in the direction orthogonal to the medium feeding direction in plan view, air supply via the guide unit and air blasting from the air blasting port can be simultaneously performed.

In the feeding device of the tenth aspect, the second medium can be separated from the first medium in a state where the first medium is stuck.

In the feeding device of the eleventh aspect, compared to a configuration where the blasting unit is stopped for the period from air supply start to the second medium from the separating unit to feeding start of the first medium by the feeding unit, the double-feeding of the media can be prevented.

In the feeding device of the twelfth aspect, control of the blasting unit is simplified compared to a configuration where the blasting unit repeats air blasting and air blasting stopping during the feeding job of the media.

In the feeding device of the thirteenth aspect, compared to a configuration where the air blasting force of the blasting unit is greater than the medium sticking force of the feeding unit, a failure of delivery of the downstream end of the first medium in the medium feeding direction to the feeding section can be prevented.

In the feeding device of the fourteenth aspect, compared to a configuration where air blasting from the blasting unit is performed before air supply from the separating unit, the double-feeding of the media can be prevented.

In the feeding device of the fifteenth aspect, compared to a configuration where air blasting from the blasting unit is stopped after the feeding start of the first medium, an increase in power consumption caused by operation of the blasting unit is prevented.

Hereinafter, an example of an exemplary embodiment according to the present disclosure will be described based on the drawings.

First, a configuration of an image forming apparatus <NUM> according to the present exemplary embodiment will be described. <FIG> is a schematic view showing the configuration of the image forming apparatus <NUM> according to the present exemplary embodiment.

An arrow UP shown in the drawings indicates an upward direction of the apparatus (specifically, a vertically upward direction), and an arrow DO indicates a downward direction of the apparatus (specifically, a vertically downward direction). In addition, an arrow LH shown in the drawings indicates a leftward direction of the apparatus, and an arrow RH indicates a rightward direction of the apparatus. In addition, an arrow FR shown in the drawings indicates a forward direction of the apparatus, and an arrow RR indicates a rearward direction of the apparatus. Since the directions are directions determined for convenience of description, an apparatus configuration is not limited to the directions. The term "apparatus" in each direction of the apparatus is omitted in some cases. That is, for example, the "upward direction of the apparatus" is simply referred to as the "upward direction" in some cases.

In addition, in the following description, an "up-down direction" is used to mean "both of the upward direction and the downward direction" or "any one of the upward direction or the downward direction" in some cases. A "right-left direction" is used to mean "both of the rightward direction and the leftward direction" or "any one of the rightward direction or the leftward direction" in some cases. The "right-left direction" can also be referred to as sideways, a lateral direction, and a horizontal direction. A "front-rear direction" is used to mean "both of the forward direction and the rearward direction" or "any one of the forward direction or the rearward direction" in some cases. The "front-rear direction" can also be referred to as sideways, a lateral direction, and a horizontal direction. In addition, the up-down direction, the right-left direction, and the front-rear direction are directions intersecting each other (specifically, directions orthogonal to each other).

In addition, a symbol in which "×" is written in "∘" in the drawings means an arrow from the front toward the back of the page. In addition, a symbol in which "·" is written in "∘" in the drawings means an arrow from the back toward the front of the page.

The image forming apparatus <NUM> shown in <FIG> is an apparatus that forms an image on a recording medium P which is an example of a medium. Specifically, as shown in <FIG>, the image forming apparatus <NUM> includes a feeding device <NUM>, a transporting unit <NUM>, an image forming unit <NUM>, and a discharging unit <NUM>. Hereinafter, each unit of the image forming apparatus <NUM> will be described.

The transporting unit <NUM> shown in <FIG> is a configuration unit that transports the recording medium P in the image forming apparatus <NUM>. The transporting unit <NUM> has a function of transporting the recording medium P fed from the feeding device <NUM> to the image forming unit <NUM> and a function of transporting the recording medium P on which an image is formed by the image forming unit <NUM> to the discharging unit <NUM>.

Specifically, the transporting unit <NUM> has transporting members 14A and 14B configured by a pair of transport rollers. In the transporting unit <NUM>, the transporting member 14A transports the recording medium P fed from the feeding device <NUM> to the image forming unit <NUM>, and the transporting member 14B transports the recording medium P on which the image is formed by the image forming unit <NUM> to the discharging unit <NUM>.

The transporting members 14A and 14B are not limited to the pair of transport rollers. The transporting members 14A and 14B may be, for example, transporting members such as a transport belt and a transport drum, and it is possible to use various transporting members.

The image forming unit <NUM> shown in <FIG> is a configuration unit that forms an image on the recording medium P fed from the feeding device <NUM>. Examples of the image forming unit <NUM> include an inkjet image forming unit that forms an image on the recording medium using inks and an electrophotographic image forming unit that forms an image on the recording medium using toners.

In the inkjet image forming unit, for example, ink droplets are jetted to the recording medium from a jetting unit, and an image is formed on the recording medium. The inkjet image forming unit may form an image on the recording medium as the jetting unit jets ink droplets to a transfer body and the ink droplets are transferred from the transfer body to the recording medium.

The electrophotographic image forming unit performs, for example, each of processes, such as charging, exposing, developing, and transferring, and forms an image on the recording medium. As each of the processes, such as charging, exposing, developing, and transferring, is performed to form an image on the transfer body and the image is transferred from the transfer body to the recording medium, the electrophotographic image forming unit may form the image on the recording medium.

Examples of the image forming unit are not limited to the inkjet image forming unit described above and the electrophotographic image forming unit described above, and various image forming units can be used.

The discharging unit <NUM> shown in <FIG> is a portion to which the recording medium on which an image is formed is discharged in the image forming apparatus <NUM>. After the image is formed by the image forming unit <NUM>, the recording medium P transported by the transporting unit <NUM> (specifically, the transporting member 14B) is discharged to the discharging unit <NUM>.

The feeding device <NUM> shown in <FIG>, <FIG>, and <FIG> is a device that feeds the recording medium P. In the present exemplary embodiment, the feeding device <NUM> feeds the recording medium P in a feeding direction (specifically, the rightward direction) determined in advance. Therefore, in the feeding device <NUM>, the rightward direction is a downstream side in the feeding direction, and the leftward direction is an upstream side in the feeding direction. In addition, in the recording medium P fed from the feeding device <NUM>, a downstream end portion in the feeding direction will be referred to as a leading end portion, and an upstream end portion in the feeding direction will be referred to as a trailing end portion. In addition, in the recording medium P, a direction (specifically, the front-rear direction) intersecting the feeding direction will be referred to as a width direction, and an end portion in the width direction will be referred to as a side end portion.

Specifically, as shown in <FIG> and <FIG>, the feeding device <NUM> includes an accommodating unit <NUM>, a lifting and lowering unit <NUM> (see <FIG>), a supply unit <NUM> (see <FIG>), a feeding unit <NUM>, a separating unit <NUM>, a restricting unit <NUM>, and a blasting unit <NUM>. Hereinafter, each unit of the feeding device <NUM> will be described.

The accommodating unit <NUM> is a configuration unit that accommodates the recording medium P. Specifically, as shown in <FIG>, the accommodating unit <NUM> has a stacking portion <NUM> and a pair of side walls <NUM>. <FIG> shows one side wall <NUM> (specifically, a forward side) of the pair of side walls <NUM>.

The stacking portion <NUM> is a configuration unit on which the recording media P are stacked. Specifically, the stacking portion <NUM> configures a bottom portion of the accommodating unit <NUM> and is configured by a stacking plate (so-called bottom plate) having an upper surface 22A on which the recording media P are stacked.

Each of the pair of side walls <NUM> is disposed on each of the forward side and a rearward side with respect to the recording media P stacked on the stacking portion <NUM>. Each of the pair of side walls <NUM> faces each of a pair of side end portions of the recording media P stacked on the stacking portion <NUM>, and the recording media P are positioned in the width direction (that is, the front-rear direction).

The accommodating unit <NUM> has a positioning unit (not shown) that positions the trailing end portions of the recording media P stacked on the stacking portion <NUM>. The accommodating unit <NUM> is not limited to the configuration, and various configurations can be used.

The lifting and lowering unit <NUM> is a configuration unit that lifts and lowers the recording medium P accommodated in the accommodating unit <NUM>. Specifically, the lifting and lowering unit <NUM> lifts the recording medium P such that the uppermost recording medium P is positioned at a height determined in advance (hereinafter, referred to as a feeding height) by lifting the stacking portion <NUM> and lowers the recording medium P by lowering the stacking portion <NUM>.

For example, a pulling member, such as a wire, a pushing member, such as an arm, and the like can be used as the lifting and lowering unit <NUM>. For example, the recording medium P is lifted as the stacking portion <NUM> is pulled upward by the pulling member, and the recording medium P is lowered by the weights of the recording medium P and the stacking portion <NUM>. For example, the recording medium P is lifted as the stacking portion <NUM> is pushed upward from a lower side of the stacking portion <NUM> by the pushing member, and the recording medium P is lowered by the weights of the recording medium P and the stacking portion <NUM>. The lifting and lowering unit <NUM> is not limited to the configuration, and various configurations can be used.

The supply unit <NUM> shown in <FIG> is a configuration unit that supplies air between a plurality of stacked recording media P and that floats the recording media P. The supply unit <NUM> supplies air to the plurality of recording media P positioned in a range determined in advance, including the uppermost recording medium P, among the plurality of recording media P stacked on the stacking portion <NUM>. That is, the supply unit <NUM> supplies air to the plurality of recording media P stacked on the stacking portion <NUM> in a range from the feeding height to a position thereunder determined in advance. Herein, floating the recording media P as the supply unit <NUM> supplies air between the plurality of stacked recording media P is to separate the plurality of recording media P from each other one by one and to feed one by one by supplying air between the plurality of recording media P respectively. <FIG>, <FIG>, and <FIG> schematically show a state where air is supplied to an upper portion of the plurality of stacked recording media P for floating.

In the present exemplary embodiment, as shown in <FIG>, the supply unit <NUM> has a pair of blowing units <NUM>, a pair of flow pipes <NUM>, and a pair of supply ports <NUM>.

The pair of blowing units <NUM> are configuration units that send wind (that is, air). Each of the pair of blowing units <NUM> is attached to an outer surface (that is, a surface on an opposite side to a surface facing the recording media P stacked on the stacking portion <NUM>) of each of the pair of side walls <NUM>. For example, centrifugal blowers that blow air in a centrifugal direction, such as multi-blade blowers (for example, sirocco fans), are used as the blowing units <NUM>. Axial flow blowers that blow air in an axial direction and other blowers may be used as the blowing units <NUM>.

Each of the pair of flow pipes <NUM> configures a passage through which air sent from each of the pair of blowing units <NUM> passes. One end portion of each of the pair of flow pipes <NUM> is connected to each of the pair of blowing units <NUM>, and the other end portion is connected to each of the pair of supply ports <NUM>.

Each of the pair of supply ports <NUM> is an opening part that supplies air to the plurality of recording media P stacked on the stacking portion <NUM> and is formed in each of the pair of side walls <NUM>. Each of the pair of supply ports <NUM> is on a leading end portion side of the recording media P stacked on the stacking portion <NUM> and is open to an upper portion of the side wall <NUM>.

In the supply unit <NUM>, the pair of blowing units <NUM> supply air between the plurality of recording media P stacked on the stacking portion <NUM> from both of side end portion sides (that is, the forward side and the rearward side) through the pair of flow pipes <NUM> and the pair of supply ports <NUM>.

A supply direction changing unit <NUM> is a configuration unit that changes an air supply direction between the plurality of stacked recording media P. Specifically, the supply direction changing unit <NUM> is configured by, for example, a louver that is provided at the supply port <NUM> and that has a plurality of blade plates. The supply direction changing unit <NUM> can change the air supply direction to, for example, at least one of the up-down direction or the right-left direction. The supply direction changing unit <NUM> is not limited to the louver, and other changing means may be used.

A supply region changing unit <NUM> is a configuration unit that changes an air supply region between the plurality of stacked recording media P. Specifically, the supply region changing unit <NUM> is configured by, for example, an opening and closing plate (that is, a shutter) that is provided to be movable to the supply port <NUM> and that can change at least one of an opening position or an opening area of the supply port <NUM> through movement. The supply region changing unit <NUM> can change the air supply region in, for example, at least one of the up-down direction or the right-left direction. The supply region changing unit <NUM> is not limited to the opening and closing plate, and other changing means may be used.

The supply unit <NUM> supplies air between the plurality of recording media P stacked on the stacking portion <NUM> from both of the side end portion sides (that is, the forward side and the rearward side), but is not limited thereto. The supply unit <NUM> may be configured to supply air between the plurality of stacked recording media P from one side (that is, one of the forward side or the rearward side) of both side end portions. In addition, the supply unit <NUM> may be configured to supply air from at least one side of the leading end portion or the trailing end portion of the recording medium P, instead of or in addition to supplying air from at least one side of both side end portion sides of the recording medium P between the plurality of stacked recording media P. Therefore, the supply unit <NUM> can be configured to supply air between the plurality of recording media P stacked on the stacking portion <NUM> from at least one side of the leading end portion or the trailing end portion of both side end portions.

The feeding unit <NUM> shown in <FIG>, <FIG>, and <FIG> is a configuration unit that makes the recording medium P floated by the supply unit <NUM> stick thereto and that feeds the recording medium P. Specifically, as shown in <FIG>, the feeding unit <NUM> makes the uppermost recording medium P (hereinafter, referred to as an uppermost medium P1), among the recording media P floated by the supply unit <NUM>, stick thereto and feeds the uppermost recording medium P1 to the downstream side in the feeding direction (specifically, the rightward direction) as shown in <FIG>. More specifically, as shown in <FIG> and <FIG>, the feeding unit <NUM> has a sticking body <NUM> and a moving mechanism <NUM>.

The sticking body <NUM> is a configuration body that makes the uppermost medium P1 stick to a lower surface 42A through suction. Specifically, on a trailing end portion side of a leading end portion of the uppermost medium P1 positioned at the feeding height, the sticking body <NUM> makes the uppermost medium P1 stick thereto. An overhanging portion <NUM> that overhangs to the downstream side in the feeding direction (specifically, the rightward direction) is formed at the sticking body <NUM>. As the uppermost medium P1 sticks to the lower surface 42A of the sticking body <NUM>, the leading end portion of the uppermost medium P1 is pushed against a lower surface 43A of the overhanging portion <NUM>. The lower surface 42A of the sticking body <NUM> is an example of a sticking surface.

The moving mechanism <NUM> is a mechanism that moves the sticking body <NUM> in the feeding direction with respect to a device body 12A of the feeding device <NUM>. Specifically, the moving mechanism <NUM> is a mechanism that moves the sticking body <NUM> in the right-left direction (that is, a downstream direction and an upstream direction of the feeding direction), between a suction position (a position shown in <FIG> and <FIG>) and a delivery position (a position shown in <FIG>).

Specifically, the moving mechanism <NUM> is configured, for example, by using a known mechanism such as a motor, a gear, a rack, a pinion, and a belt drive. The moving mechanism <NUM> is not limited to a certain mechanism, and various configurations can be used.

In the feeding unit <NUM>, the sticking body <NUM> makes the uppermost medium P1 stick to the lower surface 42A through suction at the suction position (the position shown in <FIG> and <FIG>), and the sticking body <NUM> is moved to the delivery position (the position shown in <FIG>) by the moving mechanism <NUM>. Then, at the delivery position, the recording medium P is delivered from the sticking body <NUM> to a pair of feeding rollers <NUM>, and the pair of feeding rollers <NUM> feed the recording medium P toward the image forming unit <NUM>.

The pair of feeding rollers <NUM> are feeding members (an example of a feeding section) that feed the recording medium P toward the image forming unit <NUM>. The pair of feeding rollers <NUM> are disposed on the downstream side in the feeding direction with respect to the sticking body <NUM> (specifically, the delivery position described above) to come into contact with each other in the up-down direction. The feeding members are not limited to the pair of feeding rollers <NUM>. The feeding members may be, for example, feeding members such as annular belts and drums, and it is possible to use various feeding members.

The feeding unit <NUM> is not limited to the configuration. For example, the feeding unit <NUM> may be configured to use a feeding member such as a belt, instead of the sticking body <NUM>. In the configuration where the annular belt is used, for example, a suction unit that makes the recording medium P stick to an outer peripheral surface of the belt through suction can be configured to be provided at an inner periphery of the belt. In a case of such an annular belt, the stuck recording medium P can be fed to the pair of feeding rollers <NUM> through circumferential motion of the belt. That is, in a case of the annular belt, the recording medium P can be fed to the pair of feeding rollers <NUM> even in a state where the belt is fixed to the device body 12A in the right-left direction.

The separating unit <NUM> shown in <FIG> and <FIG> is a configuration unit that supplies air G1 to the recording medium P (hereinafter, referred to as the next medium P2) positioned immediately below the uppermost medium P1 stuck to the feeding unit <NUM> (specifically, the sticking body <NUM>) and that separates the next medium P2 from the uppermost medium P1. The uppermost medium P1 is an example of a first medium. In addition, the next medium P2 is an example of a second medium. The next medium P2 is the recording medium P that is fed next to the uppermost medium P1 and is the recording medium P disposed adjacently below the uppermost medium P1. Specifically, the separating unit <NUM> supplies the air G1 obliquely downward (the obliquely lower left in <FIG> and <FIG>) from the downstream side to the upstream side in the feeding direction to a front surface side of the next medium P2 positioned immediately below the uppermost medium P1 stuck to the feeding unit <NUM> as shown in <FIG> and <FIG> and separates the next medium P2 from the uppermost medium P1. More specifically, the separating unit <NUM> has, for example, a supply device <NUM>, a flow pipe <NUM>, a nozzle <NUM>, and a guide surface <NUM> as shown in <FIG>.

The supply device <NUM> is a device that supplies the air G1 to the flow pipe <NUM>. The supply device <NUM> is disposed below the blasting unit <NUM>. The supply device <NUM> is an example of an air supply unit. For example, an air compressor that supplies compressed air to the flow pipe <NUM> or the like is used as the supply device <NUM>. The supply device <NUM> is not limited to the air compressor, and other supply devices may be used.

The flow pipe <NUM> configures a passage through which the air G1 sent from the supply device <NUM> passes. The flow pipe <NUM> extends along the width direction (that is, the front-rear direction) of the recording medium P and flows the air G1 along the width direction.

A plurality of nozzles <NUM> are provided along the width direction (that is, the front-rear direction) of the recording medium P with respect to the flow pipe <NUM>. Each of the plurality of nozzles <NUM> extends from the flow pipe <NUM> to a sticking body <NUM> (specifically, the overhanging portion <NUM>) side (that is, an obliquely upper left side). The nozzles <NUM> have a function of leading the air G1 supplied from the supply device <NUM> through the flow pipe <NUM> to an upper side (obliquely upper left side). The nozzle <NUM> is an example of an air supply path.

The guide surface <NUM> is disposed on the upper side (obliquely upper left side) of the nozzle <NUM>. The guide surface <NUM> is an example of a guide unit that guides the air G1 supplied (jetted) from the nozzle <NUM> obliquely downward from the downstream side to the upstream side in the feeding direction. The guide surface <NUM> is, specifically, a surface that the air G1 supplied from the nozzle <NUM> hits and is provided at a lower surface of the overhanging portion <NUM>. More specifically, as shown in <FIG>, the guide surface <NUM> is configured by a recessed portion <NUM> provided in the lower surface 43A of the overhanging portion <NUM>. The guide surface <NUM> has a bottom surface 62A of the recessed portion <NUM>, an inclined wall surface 62B on the downstream side in the feeding direction from the bottom surface 62A, and an inclined wall surface 62C on the upstream side in the feeding direction from the bottom surface 62A. An interval between the inclined wall surface 62B and the inclined wall surface 62C becomes larger toward the lower surface of the overhanging portion <NUM>. Specifically, as shown in <FIG>, the inclined wall surface 62B extends obliquely downward to the right from the bottom surface 62A. In addition, the inclined wall surface 62C extends obliquely downward to the left from the bottom surface 62A. Although the inclined wall surface 62B extends linearly from the bottom surface 62A as shown in <FIG> in the present exemplary embodiment, the present disclosure is not limited thereto. The inclined wall surface 62B may extend from the bottom surface 62A while bending in an arc shape. In addition, although the inclined wall surface 62C extends linearly from the bottom surface 62A as shown in <FIG> in the present exemplary embodiment, the present disclosure is not limited thereto. In addition, the inclined wall surface 62C may extend from the bottom surface 62A while bending in an arc shape.

Herein, in a case where the air G1 hits the guide surface <NUM> obliquely upward to the left, the hit air G1 flows along the guide surface <NUM>. Specifically, as shown in <FIG>, the air G1, which has hit the inclined wall surface 62B, flows from the inclined wall surface 62B along the inclined wall surface 62C through the bottom surface 62A. That is, the air G1 jetted from the nozzle <NUM> is guided obliquely downward (specifically, obliquely downward to the left) from the downstream side to the upstream side in the feeding direction by the guide surface <NUM>.

In the separating unit <NUM>, in a state where the sticking body <NUM> is positioned at the suction position (the position shown in <FIG> and <FIG>), the air G1 is jetted obliquely upward from the nozzle <NUM> toward the guide surface <NUM> from the downstream side to the upstream side in the feeding direction. The jetted air G1 hits the guide surface <NUM>. Then, the air G1 that has hit the guide surface <NUM> is guided by the guide surface <NUM> and is supplied obliquely downward to the front surface side of the next medium P2 from the downstream side to the upstream side in the feeding direction. Specifically, the supplied air G1 passes between the uppermost medium P1 and the next medium P2 from the downstream side to the upstream side in the feeding direction. Accordingly, the next medium P2 is separated from the uppermost medium P1.

After passing a tip (an end on the upstream side in the feeding direction) of the guide surface <NUM>, the air G1 guided by the guide surface <NUM> flows along an extension line EL1 of the guide surface <NUM> and is supplied to the front surface side of the next medium P2. Herein, the extension line EL1 is inclined at an angle θ1 with respect to the feeding direction. That is, the air G1 jetted from the nozzle <NUM> is supplied to the front surface side of the next medium P2 at an angle inclined by the angle θ1 with respect to the feeding direction as being guided by the guide surface <NUM>.

The restricting unit <NUM> shown in <FIG> is a configuration unit that restricts the movement of the next medium P2 to the downstream side in the feeding direction. Specifically, the restricting unit <NUM> is configured by a restricting wall disposed between the accommodating unit <NUM> and the pair of feeding rollers <NUM> (specifically, the feeding roller <NUM> disposed on the lower side) in side view. The restricting unit <NUM> is formed in a plate shape extending in the up-down direction in side view.

The restricting unit <NUM> lowers the next medium P2 from the uppermost medium P1 by coming into contact with the next medium P2 fed to the downstream side in the feeding direction together with the uppermost medium P1 in response to the movement of the sticking body <NUM> to the delivery position and restricts the movement of the next medium P2 to the downstream side in the feeding direction. The restricting unit <NUM> is not limited to the configuration, and other restricting means may be used.

The blasting unit <NUM> shown in <FIG> and <FIG> is a configuration unit that blasts air G2 obliquely downward to the front surface side of the next medium P2 from the downstream side to the upstream side in the feeding direction. A blasting angle θ2 of the air G2 of the blasting unit <NUM> with respect to the feeding direction is larger than a supply angle θ1 of the air G1 of the separating unit <NUM>. For this reason, the blasting unit <NUM> has a function of pressing the next medium P2 downward. The blasting angle θ2 will be described later.

More specifically, the blasting unit <NUM> has, for example, a supply device <NUM>, a flow pipe <NUM>, and a nozzle <NUM>, as shown in <FIG>.

The supply device <NUM> is a device that supplies the air G2 to the flow pipe <NUM>. The supply device <NUM> is disposed above the feeding unit <NUM> as shown in <FIG>. For example, an air compressor that supplies compressed air to the flow pipe <NUM> or the like is used as the supply device <NUM>. The supply device <NUM> is not limited to the air compressor, and other supply devices may be used.

The flow pipe <NUM> configures a passage through which the air G2 sent from the supply device <NUM> passes. The flow pipe <NUM> extends along the width direction (that is, the front-rear direction) of the recording medium P and flows the air G2 along the width direction.

A plurality of nozzles <NUM> are provided along the width direction (that is, the front-rear direction) of the recording medium P with respect to the flow pipe <NUM>. Each of the plurality of nozzles <NUM> extends from the flow pipe <NUM> to an overhanging portion <NUM> side (that is, an obliquely lower left side). The nozzles <NUM> have a function of leading the air G2 supplied from the supply device <NUM> through the flow pipe <NUM> to the lower side (obliquely lower left side). As shown in <FIG>, in the nozzle <NUM>, a center line CL of an internal flow path is inclined at the angle θ2 with respect to the feeding direction. The air G2 is jetted from the nozzle <NUM> in a direction along the center line CL. Herein, the blasting angle θ2 is larger than the supply angle θ1 as described above. For example, the blasting angle θ2 is preferably set within a range that is larger than the supply angle θ1 and smaller than <NUM> degrees with respect to the feeding direction. Herein, in a case where the blasting angle θ2 is <NUM> degrees, the next medium P2 is easily pressed downward by the air G2 jetted from the nozzle <NUM>, but it is difficult to avoid the uppermost medium P1 stuck to the sticking body <NUM> and to blast the air G2 to the next medium P2. On the other hand, in a case of being the supply angle θ1 or smaller, the air G2 jetted from the nozzle <NUM> flows on the front surface of the next medium P2, and thereby an effect of pressing the next medium P2 downward is small.

In addition, as shown in <FIG> and <FIG>, the blasting unit <NUM> is fixed to the device body 12A. Specifically, the supply device <NUM> of the blasting unit <NUM> is fixed to a support unit 12B provided in the device body 12A. The support unit 12B is disposed above the feeding unit <NUM>.

In addition, <FIG> is a view (plan view) of the feeding device <NUM> viewed from below. As viewed in <FIG>, an air supply port 60A of the separating unit <NUM> and an air blasting port 76A of the blasting unit <NUM> are positioned on the downstream side of the lower surface 42A of the sticking body <NUM> in the feeding direction and on the inner side of the recording medium P in the width direction. Herein, the air supply port 60A refers to the tip of the guide surface <NUM> (a tip of the inclined wall surface 62C), and the air blasting port 76A refers to a tip opening of the nozzle <NUM>. In addition, positioning the air supply port 60A and the air blasting port 76A on downstream side of the lower surface 42A in the feeding direction and on the inner side of the recording medium P in the width direction refers to having (positioning) the air supply port 60A and the air blasting port 76A between extension lines EL2 (one-dot chain lines in <FIG>) extending from both ends of the lower surface 42A in the width direction of the recording medium P to the downstream side in the feeding direction along the feeding direction. In addition, as shown in <FIG>, in the present exemplary embodiment, the overhanging portion <NUM> is positioned on the downstream side of the lower surface 42A in the feeding direction and on the inner side of the recording medium P in the width direction. For this reason, the entire guide surface <NUM> is positioned on the downstream side of the lower surface 42A in the feeding direction and on the inner side of the recording medium P in the width direction.

In addition, as viewed in <FIG>, the air supply port 60A and the air blasting port 76A are shifted away from each other in the direction orthogonal to the feeding direction (herein, the same direction as the width direction of the recording medium P). Specifically, the air supply ports 60A are disposed at an interval in the width direction of the recording medium P, and a pair of air blasting ports 76A are disposed between the air supply ports 60A adjacent to each other in the width direction of the recording medium P. More specifically, the pair of air blasting ports 76A are disposed between the pair of guide surfaces <NUM> adjacent to each other.

In addition, in the present exemplary embodiment, the separating unit <NUM> and the blasting unit <NUM> are separate bodies. A pressure applied to the next medium P2 through air blasting of the blasting unit <NUM> is higher than a pressure applied to the next medium P2 through air supply of the separating unit <NUM>. Herein, a pressure difference of air to the next medium P2 may be generated by making a generation amount of compressed air caused by the supply device <NUM> of the blasting unit <NUM> larger than a generation amount of compressed air caused by the supply device <NUM> of the separating unit <NUM>, but a pressure difference of air may be generated without changing the generation amount of compressed air by making an air blasting region R2 (a region indicated by a one-dot chain line of <FIG>) with respect to the next medium P2 caused by the blasting unit <NUM> narrower than an air supply region R1 (a region indicated by a two-dot chain line of <FIG>) with respect to the next medium P2 caused by the separating unit <NUM>. For example, jetting pressures in a case of jetting air from the nozzles of the blasting unit <NUM> and the separating unit <NUM> respectively may be set to be the same. Even in this case, the air G1 that passes through the guide surface <NUM> hits the next medium P2 within a wider range than the air G2 jetted from the nozzle <NUM>. A pressure applied to the next medium P2 in the air supply region R1 becomes smaller than a pressure applied to the next medium P2 in the air blasting region R2 since the air supply region R1 is wider than the air blasting region R2.

Each part (the supply unit <NUM>, the feeding unit <NUM>, the separating unit <NUM>, the blasting unit <NUM>, or the like) configuring the feeding device <NUM> is controlled by a control unit (not shown).

As shown in <FIG>, the blasting unit <NUM> is controlled such that the air G2 is blasted for a period from supply start of the air G2 from at least the separating unit <NUM> to the next medium P2 to feeding start of the uppermost medium P1 by the feeding rollers <NUM> of the feeding unit <NUM>. Specifically, the blasting unit <NUM> is controlled such that the air G2 is continuously blasted until a feeding job of the plurality of recording media P ends. In a case where the air G2 is continuously blasted until the feeding job of the plurality of recording media P ends as described above, control is performed such that an air blasting force to the recording medium P caused by the blasting unit <NUM> is smaller than a sticking force of the recording medium P caused by the feeding unit <NUM>.

Next, workings according to the present exemplary embodiment will be described.

In the feeding device <NUM>, air is supplied between the plurality of stacked recording media P from the supply unit <NUM>, and the recording media P are floated. Next, the feeding unit <NUM> makes the uppermost medium P1 floated by the supply unit <NUM> stick thereto. Then, the separating unit <NUM> supplies the air G1 obliquely downward from the downstream side to the upstream side in the feeding direction to the front surface side of the next medium P2 positioned immediately below the uppermost medium P1 stuck to the feeding unit <NUM> and separates the next medium P2 from the uppermost medium P1. Specifically, the air G1 supplied from the nozzle <NUM> to the front surface side of the next medium P2 passes between the next medium P2 and the uppermost medium P1 and separates the next medium P2 from the uppermost medium P1. Further, in the feeding device <NUM>, the air G2 is blasted obliquely downward to the front surface side of the next medium P2 from the blasting unit <NUM> from the downstream side to the upstream side in the feeding direction. Herein, the blasting angle θ2 of the air G2 of the blasting unit <NUM> is larger than the supply angle θ1 of the air G1 of the separating unit <NUM>. For this reason, the next medium P2 can be pressed downward. Accordingly, compared to a configuration where the next medium P2 is separated from the uppermost medium P1 with only air supplied from the separating unit <NUM>, the next medium P2 can be pulled apart from the uppermost medium P1. That is, an effect of separating the next medium P2 from the uppermost medium P1 increases.

In particular, since a pressure applied to the next medium P2 through air blasting of the blasting unit <NUM> is higher than a pressure applied to the next medium P2 through air supply of the separating unit <NUM> in the present exemplary embodiment, the next medium P2 is pushed downward by the air G2 blasted from the blasting unit <NUM>. As a result, an effect of pulling the next medium P2 apart from the uppermost medium P1 (that is, a separating effect) increases.

In addition, in the feeding device <NUM> of the present exemplary embodiment, as described above, the air G1 is supplied obliquely downward from the downstream side to the upstream side in the feeding direction to the front surface side of the next medium P2 positioned immediately below the uppermost medium P1 stuck to the feeding unit <NUM>. For this reason, in the feeding device <NUM>, air is supplied in the horizontal direction (an opposite direction to the feeding direction) from the downstream side to the upstream side in the feeding direction to the front surface side of the next medium P2 positioned immediately below the stuck uppermost medium P1, and double-feeding of the recording media P may be prevented compared to a configuration where the next medium P2 is separated from the uppermost medium P1. Specifically, the next medium P2 is easily pulled apart from the uppermost medium P1 by making the air G1 from the separating unit <NUM> hit the front surface side of the next medium P2 obliquely downward from the downstream side to the upstream side in the feeding direction. The air G2 from the blasting unit <NUM> easily hits the front surface side of the next medium P2 by widening a gap between the uppermost medium P1 and the next medium P2. As a result, double-feeding of the recording media P may be prevented.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the air supply region R1 caused by the separating unit <NUM> is narrower than the air blasting region R2 caused by the blasting unit <NUM>. For this reason, compared to a configuration where the air blasting region R2 caused by the blasting unit <NUM> is larger than the air supply region R1 caused by the separating unit <NUM>, a generation amount of the blasted air (compressed air) G2 caused by the supply device <NUM> of the blasting unit <NUM> may be reduced.

In the feeding device <NUM> of the present exemplary embodiment, the blasting unit <NUM> is fixed to the device body 12A while the feeding unit <NUM> is movable in the feeding direction with respect to the device body 12A. For this reason, the blasting unit <NUM> can blast the air G2 from a fixed position toward the next medium P2. Accordingly, in the feeding device <NUM>, a failure of delivery to the feeding rollers <NUM>, which is caused as a leading end of the uppermost medium P1 (a downstream end in the feeding direction) hangs downward due to the blasting of the air G2, may be prevented compared to a configuration where the blasting unit <NUM> moves together with the feeding unit <NUM>.

In the feeding device <NUM> of the present exemplary embodiment, since the air supply port 60A and the air blasting port 76A are positioned on the downstream side of the lower surface 42A in the feeding direction and on the inner side of the recording medium P in the width direction in plan view, a distance between the air supply port 60A and the air blasting port 76A, and the next medium P2 becomes closer compared to a configuration of being positioned on the downstream side of the lower surface 42A in the feeding direction and on an outer side of the recording medium P in the width direction. Accordingly, an effect of pulling the next medium P2 apart from the uppermost medium P1 increases. As a result, a failure of delivery to the feeding rollers <NUM>, which is caused as the leading end of the uppermost medium P1 (the downstream end in the feeding direction) hangs downward due to the blasting of the air G2, may be prevented.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the air supply port 60A of the separating unit <NUM> and the air blasting port 76A of the blasting unit <NUM> are shifted away from each other in the direction orthogonal to the medium feeding direction in plan view. For this reason, in the feeding device <NUM>, compared to a configuration where the air supply port 60A and the air blasting port 76A are at the same position in the width direction of the recording medium P in plan view, interference between the air G1 from the air supply port 60A and the air G2 from the air blasting port 76A can be prevented even in a case where air supply from the air supply port 60A and air blasting from the air blasting port 76A are simultaneously performed. That is, in the feeding device <NUM>, since air interference can be prevented as described above, air supply from the air supply port 60A and air blasting from the air blasting port 76A may be simultaneously performed.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the air supply ports 60A are disposed at an interval in the width direction of the recording medium P in plan view, and the air blasting ports 76A are disposed between the air supply ports 60A adjacent to each other in the width direction. For this reason, in the feeding device <NUM>, compared to a configuration where the air blasting ports 76A are disposed on the outer sides of the air supply ports 60A adjacent to each other in the width direction of the recording medium P in plan view, the air G2 from the air blasting port 76A is easily blasted to the front surface side of the next medium P2 (in other words, the air G2 is easily blown to the next medium P2) while widening the gap between the uppermost medium P1 and the next medium P2 through air supply from the air supply ports 60A on both sides.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the supply device <NUM> of the separating unit <NUM> is disposed below the blasting unit <NUM>. In addition, the air G1 supplied from the supply device <NUM> is led upward via the flow pipe <NUM> and the nozzle <NUM>. Then, the led air G1 approaches obliquely downward through the guide surface <NUM> from the downstream side to the upstream side in the feeding direction and is supplied to the front surface side of the next medium P2. Herein, in the feeding device <NUM>, a degree of freedom of layout improves compared to a configuration where the supply device <NUM> of the separating unit <NUM> is disposed on the same side (herein, upper side) as the blasting unit <NUM> since the separating unit <NUM> and the blasting unit <NUM> are assigned up and down.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the feeding unit <NUM> is provided with the overhanging portion <NUM> that overhangs toward the downstream side in the feeding direction. In addition, the lower surface 42A of the sticking body <NUM> and the lower surface 43A of the overhanging portion <NUM> that configure the feeding unit <NUM> are connected to each other in the feeding direction. In addition, the guide surface <NUM> is provided at the lower surface 43A of the overhanging portion <NUM>. Herein, although the air G1 jetted from the nozzle <NUM> is supplied to the next medium P2 through the guide surface <NUM>, some air G1 flows from the tip of the inclined wall surface 62C (air supply port 60A) along the lower surface 43A of the overhanging portion <NUM>. In a case where the uppermost medium P1 is stuck to the lower surface 42A, which is the sticking surface, as the lower surface 42A and the lower surface 43A are connected to each other in the feeding direction, that is, there is no step between the lower surface 42A and the lower surface 43A, some air G1 (see <FIG>) flows from the lower surface 43A to the upstream side in the feeding direction through a back surface of the uppermost medium P1. Accordingly, in a state where the uppermost medium P1 is stuck (a state where the uppermost medium P1 is unlikely to be peeled from the sticking surface), the next medium P2 is easily peeled from the uppermost medium P1 since the air G1 can be supplied between the uppermost medium P1 and the next medium P2. That is, the next medium P2 is easily separated from the uppermost medium P1.

In addition, in the feeding device <NUM> of the present exemplary embodiment, air blasting by the blasting unit <NUM> is performed for a period from air supply start to the next medium P2 by at least the separating unit <NUM> to feeding start of the uppermost medium P1 by the feeding rollers <NUM> of the feeding unit <NUM>. Herein, in the feeding device <NUM>, the double-feeding of the recording media P may be prevented compared to a configuration where the blasting unit <NUM> is stopped for a period from air supply start to the next medium P2 by the separating unit <NUM> to feeding start of the uppermost medium P1 by the feeding unit <NUM>.

In addition, in the feeding device <NUM> of the present exemplary embodiment, air blasting by the blasting unit <NUM> is continuously performed until the feeding job of the plurality of recording media P ends. For this reason, in the feeding device <NUM>, air blasting by the blasting unit <NUM>, that is, control (for example, on-off control) of the blasting unit <NUM> is simplified compared to a configuration where blasting and stopping are repeated during the feeding job of the plurality of recording media P.

In addition, in the feeding device <NUM> of the present exemplary embodiment, the air blasting force of the blasting unit <NUM> is smaller than the sticking force of the feeding unit <NUM>. Accordingly, in the feeding device <NUM>, compared to a configuration where the air blasting force of the blasting unit <NUM> is greater than the sticking force of the feeding unit <NUM>, the failure of delivery to the feeding rollers <NUM> may be prevented since hanging of the leading end (downstream end) of the uppermost medium P1 in the feeding direction is prevented.

An image is formed on the recording medium P fed from the feeding device <NUM> by the image forming apparatus <NUM> of the present exemplary embodiment. Herein, in the image forming apparatus <NUM>, the air G1 is supplied in the horizontal direction from the downstream side to the upstream side in the feeding direction to the front surface side of the next medium P2 positioned immediately below the stuck uppermost medium P1, and a recording media jam caused by the double-feeding of the recording media P can be prevented compared to a configuration where a feeding device that separates the next medium P2 from the uppermost medium P1 and that performs feeding is used.

Although air blasting by the blasting unit <NUM> is continuously performed until the feeding job of the plurality of recording media P ends in the feeding device <NUM> of the present exemplary embodiment described above, the present disclosure is not limited thereto. For example, as shown in <FIG>, air blasting by the blasting unit <NUM> may be performed (started) after the air G1 is started to be supplied from the separating unit <NUM> to the next medium P2. In this case, compared to a configuration where air blasting from the blasting unit <NUM> is performed before air supply from the separating unit <NUM>, air blasting by the blasting unit <NUM> can be performed on the next medium P2 after an interval between the uppermost medium P1 and the next medium P2 is widened by the separating unit <NUM>. Accordingly, the next medium P2 is easily peeled from the uppermost medium P1. In addition, air blasting by the blasting unit <NUM> may be performed after the air G1 is started to be supplied from the separating unit <NUM> to the next medium P2, and after then, may be stopped before feeding start of the uppermost medium P1 by the feeding unit <NUM>. In this case, compared to a configuration where air blasting from the blasting unit <NUM> is stopped after the feeding start of the uppermost medium P1, an increase in power consumption caused by operation of the blasting unit <NUM> is prevented.

Although the air supply port 60A of the separating unit <NUM> and the air blasting port 76A of the blasting unit <NUM> are positioned to be shifted away from each other in the width direction of the recording medium P in plan view in the feeding device <NUM> of the exemplary embodiment described above, the present disclosure is not limited thereto. For example, the air supply port 60A of the separating unit <NUM> and the air blasting port 76A of the blasting unit <NUM> may be at the same position in the direction orthogonal to the feeding direction (that is, the width direction of the recording medium P) in plan view. In a case where the air supply port 60A and the air blasting port 76A are at the same position in the width direction of the recording medium P in plan view as described above, the size of the device in the front-rear direction can be made small compared to a configuration where the air supply port 60A and the air blasting port 76A are shifted away from each other in the width direction of the recording medium P. That is, the size of the feeding device <NUM> can be reduced. In addition, in a case where the air supply port 60A and the air blasting port 76A are at the same position in the width direction of the recording medium P in plan view, by alternately performing air blasting by the blasting unit <NUM> and air supply by the separating unit <NUM>, interference between the air G2 blasted by the blasting unit <NUM> and the air G1 supplied by the separating unit <NUM> can be prevented, for example, compared to a configuration where air blasting by the blasting unit <NUM> and air supply by the separating unit <NUM> are simultaneously performed.

Although the separating unit <NUM> has the guide surface <NUM> at the lower surface 43A of the overhanging portion <NUM> in the feeding device <NUM> of the exemplary embodiment described above, the present disclosure is not limited thereto. The separating unit <NUM> may not have the guide surface <NUM> at the lower surface 43A of the overhanging portion <NUM>. For example, a tip side of the nozzle <NUM> is folded in the middle, and a tip opening of the nozzle <NUM> may face a direction along the extension line EL1 of the guide surface <NUM>. Also in this case, the same effect as the configuration having the guide surface <NUM> is obtained. The tip opening of the nozzle <NUM> herein is an example of the air blasting port of the exemplary embodiment of the present disclosure. In addition, a member that has the guide surface <NUM> separately from the overhanging portion <NUM> may be fixed to the device body 12A. Also in this case, the same effect as in the exemplary embodiment described above is obtained.

Although the nozzle <NUM> of the blasting unit <NUM> faces the overhanging portion <NUM> side (obliquely downward to the left) and the air G2 is jetted from the tip opening of the nozzle <NUM> in the feeding device <NUM> of the exemplary embodiment described above, the present disclosure is not limited thereto. For example, as shown in <FIG>, the air G2 jetted from a nozzle (not shown) of a blasting unit <NUM> may be blasted to the front surface side of the next medium P2 through a guide surface <NUM>. Also in this case, a supply device (not shown) and a flow pipe (not shown) of the blasting unit <NUM> may be disposed below the feeding device <NUM> like the separating unit <NUM> or may be disposed at other places. Accordingly, a degree of freedom of layout inside the feeding device <NUM> improves. The reference sign 84A in <FIG> means an end of the guide surface <NUM> and is an example of the air blasting port. In addition, the reference sign EL3 means an extension line of the guide surface <NUM>, and the air G2 flows toward the next medium P2 along an extension line EL3.

Although the pressure applied to the next medium P2 through air blasting of the blasting unit <NUM> is higher than the pressure applied to the next medium P2 through air supply of the separating unit <NUM> in the feeding device <NUM> of the exemplary embodiment described above, the present disclosure is not limited thereto. In a case where the blasting angle θ2 of the air G2 of the blasting unit <NUM> is larger than the supply angle θ1 of the air G1 of the separating unit <NUM>, an effect of pulling the next medium P2 apart from the uppermost medium P1 is obtained.

Claim 1:
A feeding device (<NUM>) comprising:
a supply unit (<NUM>) that supplies air between a plurality of stacked media (P) and that floats the media (P);
a feeding unit (<NUM>) that makes the media (P) floated by the supply unit (<NUM>) stick thereto and that feeds the media (P); and
a separating unit (<NUM>) that supplies the air (G1) obliquely downward to a front surface side of a second medium (P2) positioned immediately below a first medium (P1) stuck to the feeding unit (<NUM>) from a downstream side to an upstream side in a medium feeding direction and that separates the second medium (P2) from the first medium (P1);
the feeding device (<NUM>) being characterized in further comprising:
a blasting unit (<NUM>, <NUM>) that blasts the air (G2) obliquely downward to the front surface side of the second medium (P2) from the downstream side to the upstream side in the medium feeding direction and that has a blasting angle (θ2) of the air (G2) with respect to the medium feeding direction larger than a supply angle (θ1) of the air (G1) of the separating unit (<NUM>).