Image forming apparatus |
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申请号 | EP95111431.3 | 申请日 | 1995-07-20 | 公开(公告)号 | EP0694409A2 | 公开(公告)日 | 1996-01-31 |
申请人 | CANON KABUSHIKI KAISHA; | 发明人 | Takanaka, Yasuyuki, c/o Canon K.K.; | ||||
摘要 | This invention relates to an image forming apparatus comprising: feeding means for attaching the recording medium and feeding the recording medium in a predetermined feeding direction; image forming means for forming images according to image information on the recording medium fed by the feeding means; and separating means for separating the recording medium from the feeding means in a direction angled from the feeding direction of the feeding means. The feeding means is located on a downstream side of the image forming means and is separating the recording medium from the feeding means by pushing the recording medium from non-recording face side thereof to recording face side thereof while the recording medium is stopped during intermittent feeding. | ||||||
权利要求 | |||||||
说明书全文 | This invention relates to an image forming apparatus feeding a recording medium made of fabric or paper which is continuously fed on feeding means by making it cling to the feeding means, by separating the recording medium from the feeding means after forming an image on the recording medium. Known image forming apparatuses such as screen printing machines or ink jet printing machines have been adapted to processes in which images are continuously recorded by intermittently feeding the recording medium by a predetermined length after each image for a portion of the predetermined length has been recorded on the halted recording medium. For example, as disclosed in Japanese Patent Publication No. Showa 60-31,728 and Japanese Unexamined Patent Publication No. Heisei 5-212,851, such an image forming apparatus attaches a recording medium to a conveying belt of a feeding unit, separates the recording medium from the conveying belt at a separation zone located at the end of the feeding unit after the medium has passed through its image recording section, and feeds the recording medium to the subsequent process such as a rolling-up process by a delivery roll. Such an image forming apparatus can separate the recording medium without providing any specific member to actively pull off the recording medium from the feeding unit, since the recording medium is supplied in a continuous form, and since the conveying belt is wound so that the recording medium is guided with rollers or the like from the separation zone to the subsequent process. More specifically, as shown in Fig. 20, a drive motor not shown gives a delivery roller 51 a certain torque for rolling up, so that the recording medium P with an image formed is separated from a conveying belt 52 at a separation position B located on a downstream side of a recording unit 53. While the recording medium P is stopped on the conveying belt 52, a recording head 53a of the recording unit 53 travels in the widthwise direction of the recording medium P to record an image of a constant length L. During this recording, the separation position B of the recording medium P, due to the torque for rolling up, slightly and gradually moves to a separation position B1 or toward the recording unit 53 on its upstream side, thereby rendering the conveyance route of the recording medium P shift to a position P'. Such a torque for rolling up for the delivery roller 51 is designed so that the distance between the position B and the position B1 becomes the same as the length L. A feeding unit 54 intermittently feeds the recording medium P by the length L upon completion of recording of the length L. The feeding unit 54 intermittently feeds the recording medium P with high speed to make the time for non-printing shorter and increase the recording speed as of continuous image in total. The intermittent feeding speed is much higher than the separation speed of the medium during image recording, or distance between B and B1 divided by recording time for the length L, and is usually one tenth of the recording time for the length L. Accordingly, while intermittently fed, the recording medium P is little separated from the belt 52, so that the separation position B1 shifts to the separation position B. As a result, the recording medium P is intermittently separated with a constant intervals, or the distance between B and B1, as equivalent to the length L. With this image forming apparatus, however, the recording medium P has different times for clinging to the conveying belt 52 between the medium's separation stagnant portion and the medium's separation active portion. That is, since the recording medium P in the medium's separation active portion is gradually separated, the recording medium P in the medium's separation active portion is immediately separated from the conveying belt 52 when reaching the separation position, whereas the recording medium P in the medium's separation stagnant portion clings to the conveying belt 52 for a period as much as the recording medium P is intermittently being fed. Therefore, separation marks remain at boundaries between the active portion and the stagnant portion, because drying conditions of the recording medium after recording are so different between the active portion at which the medium has been already separated and the stagnant portion at which the medium is still clinging. If the image forming apparatus continuously records images, separation marks appear so as to form striped patterns 55 as shown in Fig. 21, thereby impairing image quality. Although, to separate the recording medium P, the torque for rolling up is set so that the tension occurring in the recording medium P is substantially equal to or a little greater than the attaching force of the conveying belt 52, the attaching force tends to be deteriorated due to repeats of separations when the apparatus is used continuously. When the attaching force is deteriorated, the tension substantially surpasses the attaching force, so that the separation position advances closer to the recording unit 53, or on an upstream side, from the normal position in comparison with that before the attaching force is deteriorated. Consequently, the image recording face of the recording medium P may contact a frame 53b of the recording unit 53 prior to the intermittent feed, thereby impairing image quality due to medium's wear-out. Moreover, if separations occur in the recording unit 53, the recording medium P is floated at the unit and disturbs operation of the recording head 53a. When a drier 55 is as shown in Fig. 20 mounted at a position before the recording medium P is rolled up on the downstream side of the separation position B and when the drier 55 heats and dries the recording medium P with a constant temperature, the recording medium P comes close to the drier 55 if the separation advances, thereby producing drying irregularity, and as a result, impairing image quality due to irregularity of density or hue. The separation may begin at which the maximum tension is applied, and a line at which the medium P separates from the belt may irregularly curve, where widthwise uneven tension is exerted to the recording medium P when the apparatus initially starts with changes of the recording medium's type such as thickness and fabric thereof. Irregular stripe patterns may occur on the recording medium P in such a case. If the separation advances locally due to the widthwise uneven tension, the image recording face may, as described above, contacts other members, thereby impairing image quality. In contrast, if the tension is substantially weaker than the attaching force of the conveying belt 52 at any portion, the separation tends to retard, and the roller of the feeding unit 54 may irregularly wind the recording medium P as shown by a separation position B2 in Fig. 20. In such a case, image quality may be impaired due to contacts and wear-out between image recording faces, and the image forming apparatus may be broken due to extraordinarily winding of the recording medium P occurring at an inner part of the feeding unit 54. Moreover, since the distance between recording medium P and the drier 55 becomes larger, the image forming apparatus cannot adequately dry the recording medium P, and as a result, irregular density or hue may occur, thereby impairing image quality. It is an object of the invention to provide an image forming apparatus preventing striped separation marks from occurring when a recording medium is separated from conveying means to record high quality image. It is another object of the invention to provide an image forming apparatus preventing the separation of the recording medium from excessively advancing toward an image forming means, preventing image quality from being impaired due to medium recording face's contacts to other parts, and preventing the image forming means from improperly operating due to floating of the recording medium. It is yet another object of the invention to provide an image forming apparatus preventing the image recording faces of the recording medium from contacting to each other or wearing out due to retardation of separation of the recording medium and preventing the recording medium from being wound in conveying means. It is a further object of the invention to provide an image forming apparatus keeping distance of the recording medium to a drier in constant notwithstanding advancement or retardation of the separation of the recording medium and preventing image quality from being impaired.
According to the construction of (1), the separating means allows the recording medium to smoothly separate from the feeding means during feeding period of the intermittent feeding, so that the recording medium is continuously separated while image is recorded, or during stop operation of the intermittent feeding, and while image is recorded, or during feeding operation of the intermittent feeding. According to the construction of (2), the image forming apparatus can maintain the separation line of the recording medium within a proper zone using the detecting means, and can prevent the recording medium from contacting to or being wound by other members. According to the construction of (3), the recording medium is evenly dried on the plane formed by the guide member through constant interval between the recording medium and the drying means. The above and other objects and features of the invention are apparent to those skilled in the art from the following preferred embodiments thereof when considered in conjunction with the accompanied drawings, in which:
Referring to Figs. 1, 2, an image forming apparatus according to a first preferred embodiment of the invention is shown. The numeral 1 represents a recording unit as image forming means, which is equipped with an ink jet recording head 1a. The recording head 1a records images on a recording medium P (or sheet P: such as cloth and paper) supplied in a continuous form, in a range of a predetermined length L (recording length) and a width W1 (= the width of the recording medium P). The image forming means of this apparatus adapts an ink jet recording method in which the recording head 1a discharges ink to make recording. That is, this recording head 1a includes fluid outlets (orifices) as very fine nozzles, fluid passages, energy operation portions provided at a part of the respective fluid passages, and energy generating means for generating droplet forming energy to operate to the fluid located at the energy operation portion. As energy generating means for generating such energy, there are a recording method using an electric-mechanic converter such as a piezoelectric device, a recording method using energy generating means that heats ink by radiation of electromagnetic wave such as laser beam and discharges droplets by this heat operation, a recording method using energy generating means that heats fluid by an electrothermal converter such as a heating device having a heating resistor and discharges the fluid, and the like. The recording head used for an ink jet recording method, among them, in which the thermal energy compels the fluid to be discharged, is capable of high resolution recording because the fluid outlets (orifice) for forming droplets to be dischrged and discharging recording droplets can be arrayed with high density. The recording head, among them, in which the electric-thermal converter is used as the energy generating means, is readily made compact and has an advantage, because of sufficiently utilizing IC technology or micro fabrication technology accompanied with recent technological progresses in the art of semiconductor and significant improvements of reliability, easily being assembled with high density, and rendering manufacturing costs inexpensive. The numeral 2 is a feeding unit roller for supplying the recording medium P given in a form of a roll. The numeral 3 is a feeding unit, as a feeding means, for feeding the recording medium P fed from the feeding unit 2. The feeding unit 3 has an endless conveying belt 3c coated with a sticking agent and tensioned between a drive roller 3a and a tension roller 3b. A clinging roller 3d in contact with the tension roller 3b with pressure attaches the recording medium P on the conveying belt 3c. The driven roller 3a is intermittently fed by the predetermined length L. The numeral 4 represents a winding unit as winding means, and winds the recording medium P on which recording has been made, around a winding roller 4c by guide rollers 4a, 4b. The winding roller 4c is rotationally driven by a driven motor not shown and winds up the recording medium P. The numeral 5 represents a cleaner for cleaning and rinsing the conveying belt 3c. The cleaner 5 removes dusts or the like clung onto the conveying belt 3c from fabric or paper used as the recording medium P and cleans the medium P. The numeral 6 represents a separator, which pushes the recording medium P from a non-recording face side P2 toward a recording face side P1 and, at a separation position B on a downstream side of the recording unit 1, separates from the conveying belt 3c the recording medium P in an upper direction S angled q from a feeding direction R of the feeding unit 3. The numeral 7 represents a control displaying respective operations of the image forming apparatus and being manipulated by operators with keys thereof. An operator can ordinarily pay attention to the respective operations of the image forming apparatus with a monitor 7a while standing near the control 7, and can observe the images formed on the recording medium P on which recording is made and which brought in a watching zone A located over the recording unit 1 on a feeding route of the winding unit 4, to evaluate the images. In case that the operator identifies an unexpected image due to mistaken input of image data or defective recording due to malfunction of the recording head 1a, the operator can immediately stop the operation of the image forming apparatus by the control 7, and after giving proper adjustments, the operator can restart the ordinary image recording operation. The apparatus cannot wind the recording medium P immediately after image recording because the ink does not adequately permeate into the recording medium P, so that the recording medium P is passed through a dry route T guided by the guide rollers 4a, 4b after separated from the conveying belt 3c and then wound by the winding roller 4c. To realize both of such observation by operator's eyes and establishment of the dry route, the angle q of the recording medium P with respect to the separation position B is set in a range between 70° and 120° , and preferably, at 90° , in an apparatus in which images are recorded on a horizontal plane. In the image forming apparatus, the recording head 1a reciprocally travels in K direction shown in Fig. 2, thereby recording images of a width L by a width W2 which is broader than the width W1 of the recording medium P. That is, a recording medium P such as fabric has its left and right sides P4 with indefinite wavy curving ends, so that it is difficult to assure its margins. Therefore, the apparatus records in excess of the width W1 of the recording medium P and never remains a non-recorded portion on the recording medium P. Notedly, the width W2 does not excess the width W3 of the conveying belt 3c nor records images outside of the conveying belt 3b (W1 < W2 < W3). Thus, extraneously recorded portions 3e at which images are recorded extraneously outside the recording medium P are formed on the conveying belt 3c. When the recording medium P separates from the conveying belt 3c, dusts coming out of the non-recording face side P2 or left and right sides P4 the recording medium P, such as fibers in the case of a fabric or paper dusts in the case of a paper, cling to sticky areas. The cleaner 5 removes and cleans the extraneously recorded portions 3e and dusts. In the cleaner 5, as shown in Fig. 1, a brush 5b is formed around a cleaning roller 5a. The cleaning roller 5a is dipped in a bath 5c for storing cleaning liquid. The cleaning roller 5a is in contact with the conveying belt 3c and, while contacting, cleans a face of the belt by being revolved in opposition to the belt proceeding direction. In particular, when a dispersion ink is used as ink, an anion related dispersant or a surface active agent, or a compound dispersing pigments, is used as the cleaning liquid. Referring to Figs. 1, 2, detailed constitution of the separator 6 is described. The numeral 6a is a separation roller rotatably supported for pushing the recording medium P from the non-recording face side P2 to the recording face side P1. The numeral 6b is a supporting arm for supporting both ends of the separation roller 6a. The numeral 6c represents a cylinder for reciprocally moving the supporting arm 6b in arrow directions Q1, Q2 by pneumatic or hydraulic pressure. The numeral 6d is a plate for the cylinder 6c. Notedly, a mechanism in which combination of a motor and a screw allows reciprocal movement, can be use in lieu of the cylinder 6c. The separator 6 is as shown in Fig. 1 placed near to the separation position B; the separation roller 6a is in contact with the recording medium P on a downstream side of the separation position B by the distance D. As shown in Fig. 2, width W4 of the separation roller 6a is broader than the width W1 of the recording medium P, so that the separation roller 6a presses with the entire width the recording medium P. In operation of the separator 6, the conveying belt 3c is stopped during image recording of the recording head 1a, and the recording medium P made to cling onto the conveying belt 3c is also stopped. The winding unit 4 applies a constant tension to the recording medium P by drive means such as a drive motor, not shown, or electromagnetic friction clutch. This tension is substantially necessary force to pull the recording medium P away from the sticking agent on the conveying belt 3c, and the separation speed is changeable according to the boundary condition between the sticking agent and the non-recording face P2 and according to the tension applied to the recording medium P. The separation roller 6a travels in arrow Q1 direction by the cylinders 6c, 6c and pushes the recording medium P to separate it from the conveying belt 3c. The separation line P3 at which the recording medium P separates from the conveying belt 3c moves toward the recording unit 1 located on the upstream side thereof from the downstream side in the feeding direction of the recording medium P. The recording medium P separates from the belt by the separation roller 6a traveling in the arrow Q1 direction while ceasing to be fed intermittently. When the recording head 1a finishes image recording of the length L, the drive motor, not shown, of the feeding unit 3 drives the drive roller 3a and intermittently feeds the recording medium P. At that time, the separation roller 6a travels in arrow Q2 direction while pushing the non-recording face P2. Although the separation line P3 moves toward the downstream side along with the recording medium that intermittently fed, the recording medium P is separated even during the feeding period of the intermittent feeding by controlling the traveling speed of the separation roller 6a to be a little slower than intermittent feeding speed. The separation roller 6a placed near the separation position B guarantees continuous separation of the recording medium P. The separation roller 6a pushes the recording medium P within a range of distance D, which is better as shorter, and which begins from the separation position B. Therefore, the recording medium P takes little stretches across the width W1, thereby making the separation line straight, and thereby eliminating local advance and retard of the separation. The separation roller 6a contacts the recording medium P with the non-recording face P2 thereof and is driven to revolve by the recording medium P conveyed for taken-up, so that the recording medium P remain free from being worn out at the non-recording face P2, from being napped when made of a fabric, and from being damaged. The recording medium P can be continuously conveyed without formation of stripe patterns as marks due to separation, and the image forming apparatus can smoothly separate the recording medium P from the conveying belt 3c, thereby recording images with high quality. Notedly, the drive of the winding roller 4c can be controlled in various ways. That is, the winding roller 4c may be rotated with a taking-up speed more than the feeding speed of the feeding unit to give a tension to the recording medium P. The winding roller 4c may be stopped or rotated with slower speed while the feeding unit 3 feeds the recording medium P, to let the feeding unit 3 do separation work by its feeding movements. When the winding roller 4c is rotated with slower speed, the separator 6 can be cooperated with the roller 4c to eliminate the recording medium P from flagging. Referring to Figs 3 to 5, modified separators are shown. In Fig. 3, the separation roller 6a' is placed so that the separation position B is located on a downstream side in a feeding direction of a virtual plane as a downward extension of a plane commonly contacting with the guide roller 4a and the separation roller 6a'. The separation roller 6a' operates in the same manner as the separation roller 6a' above. The separation roller 6a' stops while the feeding unit ceases to intermittently feed the recording medium P, and therefore, the recording medium P is separated by the tension given by the winding roller 4c. The separation of the recording medium P may advance within a section m from the separation position B to a cross line C1 intersecting the virtual plane C with the conveying belt 3c. The cross line C1 is designed not to reach the recording unit 1. When the feeding unit 3 feeds the recording medium P intermittently, the separation roller 6a travels in the arrow Q1 direction by a half of period that is required for one cycle of intermittent feeding and travels in the arrow Q2 direction by the remaining half to return to the original position. By such operation of the separation roller 6a', the recording medium P is separated even during the feeding period of the intermittent feeding, as well as during the stop period of the intermittent feeding, so that the recording medium P is continuously separated from the conveying belt 3c and is allowed to be with high quality recorded without being formed with stripe patterns due to marks of separation. Since the separation roller 6a' is traveled only during the feeding period of the intermittent feeding, this apparatus can reduce the operation time of the drive mechanism such as cylinders 6c, 6c or the like, thereby enabling its life span to extend. Referring to Fig. 4, another constitution of the separator 6 is shown. A supporting arm 6b' is rotatably supported by a shaft of the guide roller 4a at one end thereof and supports the separation roller 6a at the other end thereof so that the separation roller 6a can rotate. A cylinder 6c' is connected at the center of the supporting arm 6b', or at a position distance M1 away from the guide roller 4a. Where the distance between the guide roller 4a and the separation roller 6a is M2, the stroke of the separation roller 6a in arrow T1 direction is calculated by the stroke of the cylinder 6c' in the arrow T1 direction multiplied by M2/M1, so that the cylinder 6c', even if having a small stroke, obtain necessary movement amount to separate the recording medium P from the conveying belt 3c. Fig. 5 shows a modification when the feeding route of the recording medium P is different. The recording medium P is attached onto a conveying belt 3c' by a clinging roller 3d' at the lower side of a feeding unit 3' and is recorded by a recording head 1a' in an area of length L. The recording medium P is separated from the conveying belt 3c' at the separation position B and is wound by the winding roller 4c after passing through the guide rollers 4a, 4b. A separation roller 6a'' is arranged over a drive roller 3a', or at a downstream position of the separation position B by distance D, and pushes the recording medium P from the non-recording face side P2 of the medium. The separation roller 6a'' does not move during image recording, or during the stop period of intermittent feeding, and the winding roller 4c provides tension to separate the recording medium P from the conveying belt 3c'. The separation roller 6a'' then moves in arrow Q3 direction during the feeding period of the intermittent feeding to separate the recording medium P. As well as the modification shown in Fig. 3, the separation position B is placed on a downstream side of the cross line C1 at which the virtual plane C and the conveying belt 3c' intersects with each other. The separation roller 6a'' moves in the arrow Q3 direction in the first half of the intermittent feeding period and in the arrow Q4 direction in the second half. The same effects as the modification shown in Fig. 3 can be obtained in this modification in which the recording medium P is conveyed through the feeding route constituting an upright proceeding face to record images. Notedly, a member having low resistance against friction and high sliding-ability, such as a fixed guide plate or like on the surface of which fluororesin is coated, in lieu of the separation rollers 6a, 6a', 6a'', allows the apparatus to obtain the same effects. Referring to Figs. 6,7, another embodiment of the image forming apparatus is shown. Duplicated description is omitted for the sake of simplicity, while the same member is given to the same reference number as in the embodiment above. In Fig. 6, a sensor 8 constituted of a non-contact disposition meter or whatever is arranged, as detecting means for detecting a position at which the recording medium P separates from the feeding unit 3, on the upstream side of the separation roller 6a. The sensor 8 transmits the signals to a controller 9, which sends drive control signals to cylinders 6c for reciprocally moving the separation roller 6a, to a drive motor, not shown, for driving the drive roller 3a in the feeding unit 3, and to a drive motor, not shown, for driving the winding roller 4c in the winding unit 4, respectively, thereby controlling the respective drives of those drive sources. As the control method of those drive sources, the image forming apparatus uses control of drive torque, control of feeding speed of the recording medium P, and control of reciprocal movement speed and stroke of the cylinders 6c. As shown in Fig. 7, the sensor 8 includes a detection lever 8c urged so as to contact to the non-recording face P2 of the recording medium P, photointerrupters 8a, 8b serving as optical sensors, and a photo-shield plate 8d. The detection level 8c swings together with the photo-shield plate 8d in up and down directions around a shaft 8e as the center thereof which is fixed to a side board or whatever. For the purpose of this description, the area at which the recording medium P separates normally is defined as zone n0; an upstream limitation at which the separation position B becomes out of the zone n0 and comes close to a supporting member 1b of the recording unit 1 located on an upstream side thereof, is defined as position n1; and a downstream limitation at which the recording medium P might be wound by the drive roller 3a located on the downstream side thereof, is defined as position n2. If the separation position B is located within the zone n0, the photo-shield plate 8d on the detection lever 8c prevents only the photointerrupter 8a from receiving light. If the separation position B reaches the upstream limitation position n1, the photo-shield plate 8d swings in arrow X1 direction, thereby allowing both of the photointerrupters 8a, 8b to receive light. In contrast, if the separation position B reaches the downstream limitation position n2, the photo-shield plate 8d swings in arrow X2 direction, thereby preventing only the photointerrupter 8b from receiving light. The image forming apparatus thus detects separation position B according to advance or retard of separation by the output signals from the photointerrupters 8a, 8b. In operation, if the separation position B is located within the zone n0, the separation roller 6a is reciprocally moved in arrow Q1, Q2 directions as shown in Fig. 7, and the apparatus repeatedly performs normal image recording operation (during the stop period of intermittent feeding) and feeding operation of the intermittent feeding. If the separation position B reaches, for example, the upper limitation position n1 while the separation roller 6a travels in the arrow Q1 direction, the controller 9 temporarily stops the separation roller 6a from traveling at the position. If the separation position B then comes within the zone n0, the apparatus continuously records image again. On the other hand, if the separation position B does not come within the zone n0, the apparatus immediately displays a separation advance sign on the monitor 7a of the control 7, and continues stopping of drive of the apparatus. In such a case, the apparatus takes any one of controls of: 1) reducing the drive torque of the winding roller 4c; 2) reducing the traveling speed of the separation roller 6a in the arrow Q1 direction; and 3) reducing the stroke of the separation roller 6a in the arrow Q1 direction, to change its set values. The apparatus, as well as above, may detect the separation position B, as an operation after the separation position B has reached the upstream limitation position n1, by stepwise reducing the drive torque of the winding roller 4c according to signals from the control. If the controller 9 judges that the separation position B is advancing, the apparatus takes controls of 2) or 3). In case that the separation position B continues to advance even though the apparatus has controlled or reset such parameters several times, the controller judges that the adhesive has been deteriorated or dropped, and the adhesive is replaced or new adhesive is overcoated. If the separation position B reaches the downstream limitation position n2, the apparatus takes any one or more of controls of: 1) increasing the traveling speed of the separation roller 6a in the arrow Q1 direction; 2) increasing the stroke of the separation roller 6a in the arrow Q1 direction; 3) reducing the traveling speed of the separation roller 6a in the arrow Q2 direction; 4) reducing the stroke of the separation roller 6a in the arrow Q2 direction; 5) increasing the drive torque of the winding roller 4c; 6) increasing the winding speed of the winding roller 4c; and 7) reducing the feeding speed of the conveying belt 3c. If a situation that the separation position B is at the downstream limitation position n2 continues for a certain period or more, the controller 9 judges that the separation is retarding and performs displaying to the monitor 9 and stopping the drives of the apparatus. In case that the controller 9 judges that the separation is retarding even upon controls of the control of 1∼7, the recording medium P is never separated by the separator 6 or the winding unit 4, and therefore, the operator checks the apparatus since the recording medium P has possibly jammed at the feeding unit 3 or the conveying belt 3c. After removing problem portions, the operator restarts the operation of the image forming apparatus. The image forming apparatus can keep the recording medium P in a proper range of the separation position by controlling the drives of the feeding unit 3, the winding unit 4, and the separator 6. The image forming apparatus can efficiently record images by automatically eliminating extraordinary separations and by allowing the operator to check the apparatus while the operation is stopped if the separation position goes beyond positional limitations. Accordingly, the image forming apparatus can record images with high quality and without reducing operating rate thereof. Referring to Figs. 8 to 15, other constitutions of the sensor 8 shown in the second embodiment are shown. A corner 1c, located facing the conveying belt 3c, of the supporting member 1b of the recording unit 1 is rounded or chamfered as shown in Fig. 8. The upstream limitation position n1' can be set at an upper side than above by thus forming the corner 1c, and as a result, the apparatus can take a wider zone n0' in which the separation can be done properly. This arrangement of the corner 1c allows the controls of the respective drive means by the controller 9 to be less sensitive, and therefore, the apparatus can set response and accuracy of the mechanism thereof in less restricted ways. Referring to Fig. 9, the numeral 10a is a distance sensor secured on the non-recording face P2 on the upstream side of the separation roller 6a. The distance sensor 10a detects distance n3 between itself and the recording medium P. As the distance sensor 10a, a contact type differential micro switch, a combination of the detection lever and photointerrupters, a reflection sensor, optical or acoustic, as of a non-contact type, or the like is used. The numeral 10b is another distance sensor arranged on the supporting member 1b of the recording unit 1 on the recording face P1 side of the recording medium P on a downstream side of the separation roller 6a to detect distance n4 between itself and the recording medium P. The distance sensor 10b is composed of a non-contact type reflection sensor as described above because it is disposed on the side of recording face P1 of the medium. The controller 9 controls the respective drives of the drive sources of the feeding unit 3 based on the detection signals of the detection sensor 10a, 10b. The distance n3 is for detecting separation retarded; the distance n4 is for detecting separation advanced. The controller 9 controls the drives of the drive sources of the feeding unit 3 and the separator 6 so that the recording medium P is passing at a position where the distance sensor 10a detects the distance n3 or more and where the distance sensor 10b detects the distance n4 or more. In Fig. 10, such a distance sensor 10b' is disposed on the upstream side of the separation roller 6a. Other constitution and control of the apparatus in Fig. 10 is the same as above. In Fig. 11, another distance sensor 10c, in addition to the sensor 10b' shown in Fig. 10, is provided on the non-recording face P2 side on the downstream side of the separation roller 6a along with the separation roller 6a. The distance sensor 10c is composed of a sensor of the same type as of the distance sensor 10a to detect distance n5 between itself and the recording medium P. The distance n5 is for detecting contact between the separation roller 6a and the recording medium P. According to this constitution, the apparatus can control the separation roller 6a to contact with the recording medium P without separating for a certain period or more. In Fig. 12, the distance sensor 10c is provided on the non-recording face P2 side on the downstream side of the separation roller 6a along with the separation roller 6a, in addition to the distance sensors 10a, 10b shown in Fig. 9. The apparatus with this sensor arrangement operates, is controlled, and has the effects, as well as the apparatus shown in Fig. 11. Location and assembly of the distance sensor 10b in Figs. 9 to 12 can be chosen in consideration of conveniences when the apparatus is designed. In Fig. 13, a distance sensor 10c', in addition to the sensor arrangement shown in Fig. 9, is provided on the non-recording face P2 side on the downstream side of the separation roller 6a along with the separation roller 6a. The distance sensor 10c' is composed of a sensor of the same type as of the distance sensor 10a to detect distance n5 between itself and the recording medium P. The distance sensor 10c' can be formed on the supporting arm 6b as shown in Fig. 14, so that the distance sensor 10c' and the separation roller 6a are able to reciprocally move together. Notedly, each of the sensor 8 and the distance sensors 10a, 10b (10b'), and 10c (10c') is not necessary to be a single sensor. For example, as shown in Fig. 15, the distance sensor 10c can be composed of plural sensors located at left end, center, right end in the width direction of the recording medium P. Such plural sensors are capable of detecting irregular separation in the width direction. Such irregular separation may occur right after the apparatus starts to operate or when clinging force locally deviates due to irregularity in the width direction of the recording medium P, of attaching pressure of the clinging roller 3d. The apparatus, even when such irregular separation occurs, can detect portions at which separation advanced or retarded occurs in an early stage, and can control or set the drive sources again. In Fig. 16, a modified apparatus has a separation roller 6f with a suction system 11. The separation roller 6f is formed with plural holes 6e on its round surface and is connected to a pipe 11b at its both ends. The pipe 11b is connected to a suction pump 11a. When the suction pump 11a operates, the separation roller 6f sucks the recording medium P on its round surface, thereby preventing the recording medium P from being away from itself. The apparatus ensures, by the suction system 11 thus constituted, that the separation roller 6f contacts the recording medium P without separation advanced and that the recording medium P separates from conveying belt 3c. In Figs. 17, 18, a modified apparatus has a drier 12 disposed on the downstream side of the separator 6. The numeral 12a represents a heater serving as a thermal source; the numeral 12b represents a supporting plate swingably attached to the guide roller 4a for supporting the heater 12a. The drier 12 swingably moves around the guide roller 4a as the center thereof by means of such as a motor or cylinder not shown. Notedly, between the recording unit 1 and the drier 12 formed is the watching zone A. The heater 12a has a heat element 12c and reflection plate 12d, faces the recording face of the recording medium P, and dries it with interval E. To effectuate this dry process, the apparatus may be incorporated with a blower such as a fan not shown, and may thereby blow hot air to the recording medium P. When the recording medium P moves to position P' according to separation thereof, the interval between the recording medium P and the heater 12a may become shorter. However, if the drier 12 is turned so as to maintain swinging angle φ of the supporting plate 12b of the drier 12 around the guide roller 4a as the center to be the same as angle φ between the original position and a shifted position of the recording medium P, the apparatus can maintain the interval E between the heater 12a and the recording medium P to be unchanged even after the recording medium P has shifted to the position P'. The angle φ is expressed by a formula: The image forming apparatus, by turning control of the drier 12, can dry the recording medium P uniformly and can record images with high quality. When the recording medium P is advanced, the recording face does not contact the heater 12a, so that the image recorded is not impaired. Notedly, although in this modification the drier 12 is disposed on the recording face P1 side of the recording medium P, the drier 12 may be disposed on the non-recording face P2 side of the recording medium P to obtain the same effects. Referring to Fig.19, another embodiment of image forming apparatus is shown. Duplicated description is omitted, while the same member is given to the reference number as in the embodiment above. Fig. 19 shows a modified apparatus having another drier 12' different from one shown in Figs. 17, 18. The drier 12' has a guide plate 12e serving as guide means. The guide plate 12e is secured so as to face the feeding route of the recording medium P after separation. The drier 12' constitutes together with the guide roller 4a plane h0, which is a plane in contact with the guide roller 4a and the guide plate 12e. If a plane in which the plane h0 is extended to and beyond the guide plate 12e is assumed as virtual plane F, the recording medium P is moved (P→P') to separate according to movement of the separation roller 6a always on a side of face F1 on which the virtual plane F contacts the guide plate 12e. Accordingly, the recording medium P always forms the plane h0 even if the separation advanced occurs, so that the separation may not set the recording medium P apart from the guide plate 12e. The guide plate 12e is preferably formed in a shape with a convex curving face to contact with the recording medium P uniformly. The guide plate 12e is formed in a united body with the heater 12a so as to oppose with each other with the interval E, and the drier 12' dries the recording medium P from the non-recording face P2 side thereof through the guide plate 12e. According to the constitution above, the apparatus can dry the recording medium P while maintaining interval (thermal distance) between the heater 12a and the recording medium P constant without controlling the drier 12' to move according to separation advanced or retarded of the recording medium P. Furthermore, the image forming apparatus can minimize operation stops thereof and can efficiently record images with high quality, by using distance sensors 10a, 10b, 10b', 10c, 10c' as shown in Figs 8 to 15. It is to be noted that although in the embodiments above the image forming means uses the ink jet recording method, it would be further preferable if constituted by energizing an electrothermal converter in accordance with recording signals and by discharging ink out of the ink outlet in accordance with bubble's growth and contraction occurring to the ink in use of film boiling occurring to the ink by means of thermal energy given from the electrothermal converter to record images. This method can apply to any of so called On-Demand type and Continuous type. Specifically, in the case of the On-Demand type, it is effective because, by applying at least one drive signal which corresponds to the recording information and which provides rapid temperature increasing as exceeding nucleus boiling, thermal energy is made to occur at the electrothermal converter to produce film boiling on a thermal operation face of the recording head and, consequently, to form bubbles in the liquid corresponding to the drive signals one by one. Bubble's growth and contraction discharges liquid through the opening for discharging and forms at least one droplet. If the drive signal is formed in a pulse shape, excellent discharge of liquid can be achieved and it is more preferable, since bubble's growth and contraction is properly performed immediately. This invention is further applicable to a full line type recording head having length corresponding to the maximum width of the recording medium on which the recording apparatus can record. Such a recording head can be constituted by any of a combination of plural recording heads which satisfy the length and a single recording head unitedly formed. In addition, among the recording heads of the serial type described above, a recording head fixed to the carriage, a replaceable recording head of a chip type that allows electrical connections with the apparatus body and ink supply from the apparatus body by being attached to the carriage, a recording head of a cartridge type in which an ink tank is arranged in a united body with the recording head itself, or the like can be used. It is preferable to add such as restoring means for recording heads and preliminary supplemental means, given as constitution of the recording apparatus of the invention, because they can make the effects of the invention more stable. If they are exemplified specifically, capping means against the recording heads, cleaning means, pressure or absorbing means, preheating means made of heating elements of electrothermal converter or else or their combination, and performing preliminary discharge mode for discharging as different from recording are effective for stable recording. As for kinds and number of the recording heads mounted on the carriage, in addition to one in which only one recording head is arranged corresponding to a monochrome ink, for example, they can be provided in a plural number corresponding to the plural inks having different color and density from one another. That is, for example, it is applicable, as a recording mode of the recording apparatus, not for a recording mode only for main color such as black, but for an apparatus equipped with at least either multicolor made of different colors or full color made of mixed colors, though a recording head unitedly constituted, a combination of plural pieces of heads or whatever may be used. Furthermore, although in the embodiment described above ink is described as liquid, an ink solidified at room temperature or below and softened or liquefied at room temperature, or one that an ink is liquefied when recording signal for use is applied because in the ink jet recording method it is general to control temperature so that ink's viscosity is in a stable range of discharge by adjusting temperature of the ink itself in a range from 30 °C or above to 70°C or below, can be used. In addition, it is also applicable for one in which the ink is liquefied, in any event, by application of thermal energy according to the recording signals either by preventing temperature from increasing due to thermal energy by positive use as energy for phase change from solid state to liquid state or by using ink that solidified when left as it is for the purpose of prevention of ink's evaporation, so that the liquid ink is discharged, and for the case using an ink having nature that nothing except thermal energy makes it liquefy such that when reached the recording sheet the ink already begin to solidify. Moreover, a form of the ink jet recording apparatus described above may be, in addition to one used as an image output terminal for an information processing apparatus such as a computer, a photocopier in combination with a reader or the like, one taking a form of a facsimile apparatus having transmission and receiving functions, and the like. As described above, the image forming apparatus according to the invention can separate the recording medium from the conveying belt without stops even while the recording medium is fed intermittently by the feeding unit, so that the apparatus can continuously separate the recording medium during the period for image recording, or during the stop period of the intermittent feeding, and during the period for ceasing recording, or during the feeding period of the intermittent feeding. Consequently, the image forming apparatus can smoothly separate the recording medium from the feeding unit without forming separation marks in stripe patterns, and therefore, can record images with high quality. The image forming apparatus can maintain the separation line between the recording medium and the feeding unit in a certain range; if the separation position reaches the limitation, the apparatus can control the respective drive sources to prevent the recording medium from contacting other members and from jamming; and if the separation position goes beyond the limitation, the apparatus can stop its operation. By such operations, the apparatus can suppress extraordinary separation automatically and can efficiently record images with high quality and without reducing the operation rate thereof. By drying the recording medium with constant interval between the recording medium and the drier on a plane formed by the guide member, the apparatus can maintain the thermal distance between the drier and the recording medium constant, regardless separation advanced or retarded of the recording medium, and can efficiently record images with high quality. It is to be noted that although the most preferred embodiment according to the invention is described, persons skilled in the art may consider other constitution or modifications. Therefore, this invention is not restricted to the embodiments above, other variations are covered as far as within the scope of the following claims. This invention relates to an image forming apparatus comprising: feeding means for attaching the recording medium and feeding the recording medium in a predetermined feeding direction; image forming means for forming images according to image information on the recording medium fed by the feeding means; and separating means for separating the recording medium from the feeding means in a direction angled from the feeding direction of the feeding means. The feeding means is located on a downstream side of the image forming means and is separating the recording medium from the feeding means by pushing the recording medium from non-recording face side thereof to recording face side thereof while the recording medium is stopped during intermittent feeding. |