KR101223128B1 - High precision plotting instrument having improved stability - Google Patents

Abstract

PURPOSE: A plotting instrument for precise plotting with improved stability is provided to automatically, promptly and easily place positive film on a scanner without having the fingerprint of an operator left on. CONSTITUTION: A plotting instrument for precise plotting includes a plotting instrument case(100), a transparent board(200), a scanner(300), a switch(400), an access sensing unit(500), an approach sensing unit(600), a temperature sensing unit(700), a first transferring unit(800), a second transferring unit(900), a supersonic wave generator(1000), a cooling line(1100), a cooler(1200), a compressor(1300), an exhaust fan(1400), a controller(1500) and an alarm unit(1600). The plotting instrument automatically transfers an inserted positive film(F) for scanning, and converts the film into a file, and the film is automatically drawn. Sensing temperature of the inner part in real-time, the expansion of the positive film may be blocked.

Description

High Precision Plotting Instrument Having Improved Stability

The present invention prevents the insects from approaching the periphery of the beetle in advance, thereby preventing damage to the image of the image due to the influx of the beetle and automatically transferring the inserted positive film to enable scanning and copying the positive film. The present invention relates to a precision drawing plunger with improved stability to be read out, made into a file, and automatically withdrawn.

In general, a fighter is a device for producing a topographic map using a quantum film from an aerial photo.

As a conventional fuser as described above, there is a registered Patent No. 10-0937052, which is briefly described as follows.

The fuser, the drawing base body and the scanner, the opening and closing cover, the cooling line, the cooling unit, the input unit, the temperature sensor, the touch sensor, the control unit, and the display are disclosed, and the aerial evolution in real time through the display installed on the drawing base body. The film can be checked and always scanned in the right position, and if the aerial quantification film is distorted due to external factors, the touch sensor detects this in advance and informs the operator. Deformation or expansion of the positive film in the inside of the fuser can be minimized so that external deformation does not occur through the cold air of the cooling unit.

However, in the case of the fuser, a hinge type opening / closing method is applied, so that the insects are easily approached and inflowed, and thus the insects are displayed on the image as they are scanned when the insects are seated on the positive film. Therefore, the operator had to perform the same work repeatedly, and there was an uncomfortable problem, and moreover, the conventional fuser was set by opening and closing the airlift positive film in the open state by flipping the open / closed cover to scan the airlift positive film. The cover is closed to be closed and sealed, and then the image is read through the scanner as if it is a copy of the aeronautical quantum film. It's easy to stick, and if you're going to scan the aerial There is an uncomfortable problem that the mote remains in the unknown and needs to be reworked.

In addition, the conventional fuser is very inconvenient because there is no function to inform the operator when an emergency occurs inside the fuser. As an example, when the temperature inside the fuser rises above a certain threshold (for example, the initial temperature at which the film is changed by heat), the operator cannot intuitively perceive the current state and cannot take any action. There was a problem, and if the film was damaged by heat, there was a serious problem that the aerial photographs had to be retaken.

In addition, in the case of the conventional lighter, when the fingerprint of the operator gets in the process of setting the aerial quantification film in place, there is a serious problem that the work is very uncomfortable because the post-treatment (finger trouble removal) must be separately performed.

The present invention has been made to solve the above problems, it is possible to block the influx of the blade through the high frequency to prevent the influx of the image image due to the influx of the blade while blocking the inflow of dust from the outside In addition, the purpose of the present invention is to provide an improved precision drawing plunger capable of quickly and easily placing a quantum film automatically so that the fingerprint of the operator is hardly touched on the scanner.

According to an aspect of the present invention,

The inner space is provided in a box shape, the inlet is formed on one side so that the positive film can enter and exit, the inner side is formed to support the inner side protruding inwards to support the transparent plate, the air opposite the inlet An injection pipe path interconnected with the compressor to be injected toward the inlet part, the case body having a fixing groove formed on both sides of the inlet part so that the protrusion of the opening / closing cover is detachably fixed; An opening and closing cover having a protrusion detachably coupled to the fixing groove of the case body and rotatably installed on the case body to open and close the inlet; The case with a opaque white plate which is built in the case body and spaced apart from the top of the transparent plate:

Transparent plate seated on the support so that the positive film can be seated on the top:

A scanner built into the projector case to be placed on the bottom of the transparence plate and copies the positive film placed on the transparence as if it were a copy:

Switch unit installed on the case body to be operated by the opening and closing cover to control the power ON / OFF:

The entrance detection unit installed at the entrance to detect the entrance and exit of the positive film and outputs the entrance detection signal:

Proximity detection unit is installed in the case body adjacent to the switch unit to detect the proximity object to output an object detection signal when detecting the proximity object:

Temperature sensing unit is installed between the white plate and the transparent plate of the fuser case to detect the ambient temperature and output a temperature detection signal:

A pair of first elevating units having an elevating block for elevating and descending, which is installed between the case body and the back plate and operated by a control unit to elevate and elevate the elevating block; And a first driving unit which includes a shaft rotatably inserted in the lifting block of the first lifting unit and a roller inserted and fixed on the circumferential surface of the shaft, and which is controlled by the control unit to rotate the shaft in the forward or reverse direction. First transfer unit is installed in the end direction of the main body:

A pair of second elevating units having an elevating block for elevating and descending, which is installed between the case body and the back plate and is controlled by a control unit to elevate and elevate the elevating block; And a second driving part including a shaft rotatably inserted into the lifting block of the second lifting unit and a roller inserted and fixed on the circumferential surface of the shaft, and controlled by the control unit to rotate the shaft in the forward or reverse direction. Second conveying unit installed in the longitudinal direction of the main body:

An ultrasonic circuit board which is operated by a control unit and generates a high frequency so that a high frequency can be output through a speaker; Ultrasonic generating means composed of a speaker which is operated by the ultrasonic circuit board to output a high frequency to the outside:

A first connection part of which one end is exposed to the upper surface of the case body and the other end is in the case body; A cooling unit having one end communicating with the other end of the first connection unit and transferring cold air to the surroundings; Cooling line consisting of a second connection portion of which one end is in communication with the other end of the cooling unit and the other end is exposed to the upper surface of the case body:

A cooling device unit installed between the first connection unit and the second connection unit and controlled by the controller to supply cold air to the cooling line:

Compressor installed in the case body and connected to the injection pipe line, and controlled by the controller to supply air to the injection pipe line:

Exhaust fan installed in the case body and operated by the control unit to exhaust the internal heat to the outside:

Receives power from the switch to control the compressor, receives the entrance detection signal from the entrance detection unit, and transfers the first transfer unit, the second transfer unit and the scanner in sequence, and receives the object detection signal from the proximity detection unit Operation signal is output to the ultrasonic circuit unit so that the ultrasonic wave is output through the speaker, and when the temperature detection signal is received from the temperature sensing unit and the reference value is exceeded, the controller controls the cooling unit and the exhaust fan and simultaneously outputs an emergency signal. :

It is characterized in that it comprises an alarm means for generating a sound by receiving an emergency signal from the control unit.

According to a preferred embodiment of the present invention, when the operator opens the opening and closing cover to generate a drawing image, the proximity detecting unit exposed to the outside by the opening and closing cover detects the operator to output the proximity detection signal to the control unit, the control unit By receiving this, the ultrasonic generation means is controlled for operation. In addition, the ultrasonic generating means operated by the control unit generates a high frequency to output to the outside through the speaker, through which the beetle no longer approaches the fuser to fly to another place. Therefore, since the damage of the drawing image due to the inflow of the beetle during the scanning process can be prevented through the above-described action, a more precise drawing image can be obtained.

Further, according to a preferred embodiment of the present invention, the temperature measured from the temperature sensing unit through the temperature sensing unit and the cooling line, the cooling unit, the exhaust fan, the control unit and the alarm means provided in the fuser case is higher than the predetermined reference value. When the result value is output, the control unit simultaneously controls the operation of the cooling unit and emits a warning sound to the surroundings. Therefore, through the above-described action, the positive film is gradually cooled by the cold air to prevent the positive film from being deformed by heat, thereby obtaining an accurate drawing image with almost no error from the positive film, and the operator is alerted. The sound generated from the means intuitively recognizes an emergency and has the advantage of quickly following up.

In addition, according to a preferred embodiment of the present invention, when the inlet is opened and closed so that the inlet is opened and closed through the opening and closing cover installed in the case body, even if left for a long time, the inflow of dust from the outside can be blocked and In this state, since the switch unit is kept pressed all the time, unnecessary standby power consumption can be eliminated.

Furthermore, according to a preferred embodiment of the present invention, by installing a compressor in the fuser case and producing air through the medium to blow strong air to the transparent plate, impurities in the image are detected when the positive film is scanned through a scanner. It can be prevented from being output together, so that not only a sharper image can be obtained, but also a sharper image can be obtained, which can drastically reduce the error range, making it possible to produce a more precise digital map. You lose.

Furthermore, according to a preferred embodiment of the present invention, the quantizing film is automatically and quickly and easily in such a manner that the quantizing film is disposed on the transparent plate on which the scanner is disposed through the first and second transfer units installed in the fuser case. Since it can be transported, the fingerprint of the worker is hardly buried, so there is no need for post-processing.

1 and 2 is a perspective view of the precision drawing dope improved in accordance with the present invention.
Figure 3 is a front cross-sectional view of the precision drawing fuser with improved stability according to the present invention.
Figure 4 is a side cross-sectional view of the precision drawing fuser with improved stability according to the present invention.
5 is a plan sectional view of a precision drawing fuser with improved stability according to the present invention.
Figure 6 is a block diagram showing the interrelationship between each component in the precision drawing dope improved stability according to the present invention.
7a to 7e is a view for explaining the operation of the stability of the precision drawing fuser according to the present invention.
Figure 8 is a view for explaining the process of combating the blades of insects in the precision dope for improved stability according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail.

1 to 5, the image projector for the production of precision digital map according to the present invention, the projector case 100, the transparent plate 200, the scanner 300, the switch unit 400, access detection Part 500, proximity sensing unit 600, temperature sensing unit 700, the first transfer unit 800, the second transfer unit 900, ultrasonic wave generating means 1000, cooling line 1100, cooling device Composed of the unit 1200, the compressor 1300, the exhaust fan 1400, the control unit 1500, the alarm means 1600, the inserted positive film (F) is automatically transported and quantized to enable scanning (scan) It reads the film (F) as if it is a copy, makes it into a file, automatically draws it out, and at the same time prevents the insect B from approaching the periphery of the fuser, preventing damage to the image image due to the influx of the insect B. The internal temperature is sensed in real time to block the expansion of the quantum film F by heat, thereby fundamentally causing the error of the drawing image. In case of emergency, the operator can be notified by sound to induce the worker to take prompt action.

The fuser case 100 includes a case body 110, an opening / closing cover 120, a back plate 130, and an accommodating part 140, and includes a transparent plate 200, a scanner 300, and a switch unit. 400, the entrance detection unit 500, the proximity detection unit 600, the temperature detection unit 700, the first transfer unit 800, the second transfer unit 900, the ultrasonic generating means 1000, the cooling line 1100, the compressor 1300, the exhaust fan 1400, and the controller 1500 may be protected from the outside.

The case body 110 is formed in the form of a rectangular box as a whole, and the inside of the transparent plate 200, the scanner 300, the switch unit 400, the entrance detection unit 500, the proximity detection unit 600, the temperature detection unit A space portion is provided to allow 700, the first transfer unit 800, the second transfer unit 900, the compressor 1300, and the control unit 1500 to be installed therein. In particular, the case body 110 has an inlet portion 111 having a predetermined thickness and width so that the positive film (F) can enter and exit the inside, and protrudes inward along the inner surface of the transparent plate At the same time as supporting the 200, the support piece 112, which is a reference, is formed so that the positive film F is disposed accurately at the edge, and the air is directed toward the inlet part 111 in the opposite side of the inlet part 111. An injection pipe line 113 is formed to be connected to the compressor 1300 so as to be injected, and the protrusion 121 of the opening / closing cover 120 is detachably fixed to both sides of the inlet 111. The fixing groove 114 is formed. In addition, a cooling line 1100 to be described later is installed inside the case body 110, and a cooling device 1200 connected to the cooling line 1100 is installed on an outer surface thereof. And, both sides of the case body 110, as shown in Figures 1 and 2, the exhaust fan 1400 for forcibly discharging the internal heat to the outside and the alarm means 1600 for emitting sound is external It is installed to be exposed.

The opening and closing cover 120 as a plate forming a rectangular shape as a whole, it is installed on the case body 110 to be rotatable to function to open and close the inlet portion (111). In this embodiment, both sides of the opening and closing cover 120 is formed integrally with the outwardly extending protrusions 121, wherein the protrusions 121 are detachably attached to the fixing groove 114 of the case body 110. Combined. Therefore, the opening and closing cover 120 may maintain the closed state at all times if the protrusion 121 is coupled to the fixing groove 114, so that dust may be introduced from the outside even if left unused for a long time. There is an advantage that can be cut off, and since the switch unit 400 is always pressed in the closed state, it is possible to solve the problem of unnecessary standby power consumption.

The white plate 130 is an opaque plate, and a metal material having excellent thermal conductivity is preferable. In the present embodiment, it is installed in the case body 110 is spaced apart from the upper surface of the transparent plate 200. Here, the back plate 130 is the first transfer unit 800 and the second transfer unit 900 in the case body 110 in the process of scanning the positive film (F) through the scanner 300 together It is a kind of blocking plate that blocks the image, and is a medium for transferring the cold air discharged through the cooling device unit 1200 and the cooling line 1100 to the positive film (F). According to this embodiment, the cold air supplied from the cooling unit 1200 to be described later is discharged through the cooling line 1100 in the process of moving along the cooling line 1100, and the discharged cold air is the white plate 130. It is cooled, and the cooled back plate 130 is to cool the quantizing film (F) slowly to prevent the deformation of the quantizing film (F) by heat, so that the precision of the quantizing film (F) can be minimized A picture image can be obtained.

The accommodating part 140 is a known drawer. In the present embodiment, the accommodating part 140 is installed in the lower end of the case body 110 and the positive film F is stored therein. Therefore, the operator through the receiving unit 140 can be stored in one place without storing the positive film (F) separately, it is possible to fundamentally solve the problem of loss of the positive film (F).

The transparent plate 200 is a known glass plate that is fixed to the support piece 112 so that the positive film F may be seated on the upper surface. For reference, between the support piece 112 and the transparent plate 200 to fix the support piece 112 and the transparent plate 200 through a double-sided tape and at the same time to prevent the contamination source such as dust from entering. It is desirable to.

The scanner 300 is a known device that is arranged on the bottom surface of the transparent plate 200 and reads the positive film F placed on the transparent plate 200 as if it is a copy. Since the scanner 300 is already well known in the art, a detailed description thereof will be omitted.

The switch unit 400 is a known push button switch, which is installed in the case body 110 to be operated by the opening and closing cover 120 in the present embodiment. According to this embodiment, when opening and closing the opening and closing cover 120 closing the inlet 111 of the case body 110, the button of the switch unit 400 that was pressed by the opening and closing cover 120 is When the power cut off while being connected to the front is connected, the entrance detection unit 500, the proximity detection unit 600, the temperature detection unit 700, the first transfer unit 800, the second transfer unit 900, ultrasonic generation Power is applied to the means 1000, the cooling unit 1200, the compressor 1300, the control unit 1500, and the alarm means 1600. On the contrary, when the opening and closing cover 120 is closed to close the inlet 111, the power connected to the button of the switch unit 400 by the opening and closing cover 120 is naturally cut off. Therefore, unnecessary waste of standby power can be prevented through the above-described action.

The entrance detection unit 500 is a known motion recognition sensor (motion recognition sensor), in the case of the present embodiment is installed in the inlet 111 so as to detect the entry and exit of the positive film (F) to output an entrance detection signal Function In the present embodiment, the motion recognition sensor has been described as an embodiment of the entrance detection unit 500, but this is only one embodiment, which can perform the same function as the entrance detection unit 500. Any known one can be modified.

The proximity detecting unit 600 is a known motion recognition sensor. In the present embodiment, the proximity detecting unit 600 is adjacent to the switch unit 400 so as to sense an object (for example, an operator, a beetle, etc.) in proximity. When installed in the case body 110 detects an object in close proximity to the function to output an object detection signal to the controller 1500. In the present embodiment, the motion recognition sensor is described as one embodiment of the entrance detection unit 500, but this is only one embodiment, and can perform the same function as the proximity detection unit 600. If it is, it can be modified by any known.

The temperature detecting unit 700 is a known temperature sensor, which is installed between the back plate 130 and the transparent plate 200 of the fuser case 100 to sense and output an ambient temperature in the present embodiment. Function As an example, the temperature sensing unit 700 continuously measures the ambient temperature and transmits the temperature to the control unit 1500. The control unit 1500 continuously receives the measured temperature from the temperature sensing unit 700. At this time, when a result of the temperature measured from the temperature sensing unit 700 is higher than the preset reference value is output, the controller 1500 controls the operation of the cooling unit 1200, the temperature is lower than the preset reference value Operation control to stop the operation of the ground cooling unit 1200. In the case of the temperature sensing unit 700, since it is well known in the art, a detailed description thereof will be omitted.

The first transfer unit 800 is composed of the first lifting unit 810 and the first driving unit 820, in the present embodiment is installed in the end direction (see Fig. 5) of the case body 110, the positive film ( F) automatically reciprocating along the longitudinal direction of the case body 110, the first lifting unit 810 and the first driving unit 820 constituting the first transfer unit 800 is a control unit ( Operation control). The first lifting unit 810 is a known solenoid having a lifting block 811 which is lifted and lowered. In the present embodiment, the first lifting unit 810 is installed between the case body 110 and the back plate 130 and the control unit 1500. Operation is controlled by the function to raise and lower the lifting block 811. The first driving unit 820 naturally moves up and down by the elevating block 811. For reference, the first lifting unit 810 is a pair to raise and lower the first driving unit 820 in a stable state. It is preferred that the configuration. The first driving unit 820 includes a shaft 821 rotatably inserted into the lifting block 811 of the first lifting unit 810, and a roller 822 inserted and fixed to the circumferential surface of the shaft 821. Then, the operation is controlled by the control unit 1500 to rotate the shaft 821 in the forward or reverse direction. For reference, the first driving unit 820 is a known servomotor. In addition, the roller 822 is preferably composed of a pair in order to stably transfer the positive film (F), it is preferable to form a soft rubber to minimize damage to the positive film (F). According to the present embodiment, the first lifting unit 810 and the first driving unit 820 are controlled by the control unit 1500. In the case of the first lifting unit 810, the lifting block 811 is introduced. The first driving unit 820 installed in the first lifting unit 810 is naturally lowered, and in the case of the first driving unit 820, the first driving unit 820 rotates in a clockwise direction (see FIG. 6B). 821 and roller 822 also rotate naturally. For reference, when the first driving unit 820 is lowered by the first lifting unit 810, only a portion of the roller 822 penetrates the hole of the back plate 130 to jig the upper surface of the positive film F. While pressing, the positive film F is transferred along the longitudinal direction of the case body 110.

The second transfer unit 900 is composed of a second lifting unit 910 and a second driving unit 920, like the first transfer unit 800, in the case of the present embodiment longitudinal direction (Fig. 5) and the reciprocating transfer of the positive film (F) conveyed by the first transfer unit 800 automatically along the end direction of the case body 110, the second transfer unit 900 The second lifting unit 910 and the second driving unit 920 constituting the control operation by the control unit 1500. The second lifting unit 910 is a known solenoid having a lifting block 911 that is lifted and lowered. In the present embodiment, the second lifting unit 910 is installed between the case body 110 and the back plate 130 and the control unit 1500. Operation is controlled by the function to raise and lower the lifting block 911. The second driving unit 920 is naturally raised and lowered by the lifting block 911, and the second lifting unit 910 is a pair to lift and lower the second driving unit 920 in a stable state. It is preferred that the configuration. The second driving unit 920 includes a shaft 921 rotatably inserted into the lifting block 911 of the second lifting unit 910, and a roller 922 inserted and fixed to the circumferential surface of the shaft 921. Thus, the operation is controlled by the controller 1500 to rotate the shaft 921 in the forward or reverse direction. For reference, the second driving unit 920 is a known servomotor. In addition, the roller 922 is preferably composed of a pair in order to stably transfer the positive film (F), it is preferable to form a soft rubber to minimize damage to the positive film (F). According to the present embodiment, the second lifting unit 910 and the second driving unit 920 are controlled by the control unit 1500. In the case of the second lifting unit 910, the lifting block 911 is introduced. The second driving unit 920 installed in the second lifting unit 910 is naturally lowered, and in the case of the second driving unit 920, the shaft is rotated in a clockwise direction (see FIG. 6D). 921 and the roller 922 also naturally rotates. For reference, when the second driving unit 920 is lowered by the second lifting unit 910, only a part of the roller 922 penetrates the hole of the back plate 130 to jig the upper surface of the positive film F. While pressing, the positive film F is transferred along the end direction of the case body 110. Here, the first transfer unit 800 and the second transfer unit 900 are sequentially controlled by the control unit 1500. That is, after the first transfer unit 800 is controlled by the control unit 1500 to automatically transfer the positive film F, the first transfer unit 800 automatically rises and at the same time the second transfer unit As the 900 is lowered, the positive film F is transferred to the end direction of the case body 110.

The ultrasonic wave generating means 1000 is composed of a known ultrasonic circuit board 1010 and a speaker 1020, in the case of the present embodiment is controlled by the control unit 1500 to output a high frequency to the periphery (B) In particular, it serves to block the inflow into the inlet 111. The ultrasonic circuit board 1010 and the speaker 1020 are installed adjacent to the switch unit 400 as shown in FIG. In particular, the ultrasonic circuit 1010 of the ultrasonic generating means 1000 generates a high frequency when the power is applied by the switch unit 400 and outputs the high frequency to the outside through the speaker 1020. For reference, sound waves that can be heard by animals such as humans and dogs are 20000 to 27000 hertz, while insects and pests can detect even higher sound wavelengths. This extreme stress will be utilized because it is used, and in the case of the pest control device using the ultrasonic wave is actually applied in the pest control system, detailed description thereof will be omitted. According to the present embodiment, when the worker opens the opening and closing cover 120 to generate a drawing image, the proximity detecting unit 600 exposed to the outside by the opening and closing cover 120 detects the worker to control the object detection signal. Output to the 1500, the control unit 1500 receives this to control the operation of the ultrasonic wave generating means (1000). In addition, the ultrasonic generating means 1000 operated by the controller 1500 generates a high frequency to output to the outside through the speaker 1020, through which the beetle (B) can no longer approach the fuser and other Fly to the place. Therefore, through the above-described action it is possible to prevent damage to the original image due to the influx of the beetle (B) during the scanning process can be obtained a more accurate image of the image.

The cooling line 1100 is a hollow, well-known conduit to allow cold air to flow. In this embodiment, the cooling line 1100 is installed in the case body 110 of the fuser case 100, and both ends thereof are exposed to the upper surface of the case body 110. The exposed both ends are interconnected with the cooling unit 1200. The cooling line 1100 has a first connection part 1110 whose one end is exposed to the upper surface of the case body 110 and the other end is in the case body 110; A cooling unit 1120 having one end communicating with the other end of the first connection unit 1110 and transferring cold air to the surroundings; One end is in communication with the other end of the cooling unit 1120, and the other end is composed of a second connection portion 1130 exposed to the upper surface of the case body (110). Here, the cooling line 1100 is preferably applied to a tube made of copper or aluminum material having excellent thermal conductivity.

The cooling device unit 1200 is a known cooler that continuously supplies cold air to the cooling line 1100. In the present embodiment, the cooling device unit 1200 is installed on the upper surface of the case body 110. The first connection part 1110 and the second connection part 1130 of the cooling line 1100 are installed at one side and the other side of the cooling device part 1200, respectively. The cold air generated by the cooling device part 1200 is connected to the first connection part. It is supplied to the 1110 and is discharged through the second connecting portion 1130 via the cooling unit 1120. In particular, in the process of moving the cold along the cooling unit 1120, the cold air is transferred to the surroundings through the cooling unit 1120, thereby cooling the white plate 130, and through the cold air delivered through the white plate 130 as a medium. The positive film F is cooled to block the positive film F from being deformed by heat. In addition, the cold air that has lost the refrigerant function is a repetitive circulation method in which the cool air is cooled again in the cooling device unit 1200 and supplied to the first connection unit 1110. The cooling device unit 1200 is a cooling device used in a conventional refrigerator, and its configuration is already well known in the art, so a detailed description thereof will be omitted.

The compressor 1300 is a known compressor that is installed in the case body 110 of the fuser case 100 and is connected to the injection pipe 113 of the case body 110. Operation is controlled by 1500 to supply air to the injection pipe passage 113 to blow the dust seated on the transparent plate 200 to discharge to the outside. According to the present exemplary embodiment, when the inlet 111 is opened by flipping the opening / closing cover 120 installed on the case body 110 to open and close, the button of the switch unit 400 pressed by the opening / closing cover 120 is opened. The power that was cut off while being forwardly connected is connected. At this time, the compressor 1300 is operated and controlled by the controller 1500 to produce compressed air (air), and the produced compressed air (air) is injected into the injection pipe ( It is supplied through one end of 113) and discharged through the other end, and blows dust seated on the transparent plate 200 through the discharged compressed air (air) to be discharged to the outside. Therefore, when the positive film F is scanned through the scanner 300 as described above, impurities can be prevented from being output to the image, thereby obtaining a sharper image, as well as a clear image. Since the image can be obtained, the range of the error can be significantly reduced, and thus the digital map can be produced more precisely than in the related art.

The exhaust fan 1400 is installed on both side surfaces of the case body 110 to forcibly discharge the heat inside. In the present embodiment, the exhaust fan 1400 is forced to discharge the heat inside the operation control by the controller 1500 to the outside to minimize the heat transmitted to the positive film (F) seated on the transparent plate 200 Do not allow thermal deformation due to heat. For reference, the exhaust fan 1400 is operated simultaneously with the cooling unit 1200 by the controller 1500.

The control unit 1500 receives power from the switch unit 400 to control the operation of the compressor 1300, and receives an access detection signal from the access detecting unit 500 to receive the first transfer unit 800 and the second transfer unit. Operation 900 and the scanner 300 in sequence, and receives the object detection signal from the proximity sensing unit 600 and outputs an operation signal to the ultrasonic circuit unit 1010 so that the ultrasonic wave is output through the speaker 1020, When the temperature detection signal is received from the temperature sensing unit 700 and exceeds the reference value, the cooling unit 1200 and the exhaust fan 1400 control the operation and at the same time function to output an emergency signal.

The alarm means 1600 is a known buzzer. In the present embodiment, the alarm means 1600 is installed at both sides of the case body 110 of the fuser case 100 to receive an emergency signal from the controller 1500 to generate sound. To function. Therefore, the operator can intuitively recognize the emergency situation through the warning sound and can quickly follow up.

Referring to Figures 1 and 6 to 7E will be described the operation of the present invention.

First, as shown in FIG. 7A, the opening / closing cover 120 closing the inlet 111 of the case body 110 to insert the positive film F into the interior of the fuser case 100 is illustrated. Leave it open.

As described above, when the opening and closing cover 120 closing the inlet 111 is turned down, the button of the switch unit 400 pressed by the opening and closing cover 120 is fired forward, and the cut off power is naturally connected. Detection unit 500, proximity sensing unit 600, temperature sensing unit 700, the first transfer unit 800, the second transfer unit 900, the ultrasonic wave generating means 1000, the cooling device unit 1200, Power is applied to the compressor 1300, the exhaust fan 1400, the control unit 1500, and the alarm means 1600. At this time, the proximity detecting unit 600 continuously detects (measures) the presence or absence of a nearby object. The controller 1500 transmits the temperature to the controller 1500. The temperature detector 700 continuously detects (measures) the surrounding temperature and transmits the temperature to the controller 1500. The compressor 1300 is controlled by the controller 1500. Compressed air (air) is produced, and the produced compressed air (air) is supplied through one end of the injection pipe passage 113 to the other end. To be discharged, to a dust blower mounted on the transparent plate 200, the discharged compressed air (air) as a medium Ng (blowing) is discharged through the opening portion 111 to the outside.

Then, when a predetermined time elapses, the compressor 1300 is controlled by the control unit 1500 and stopped. At this time, the operator grips both ends of the positive film F, and the inlet 111 of the case body 110 is stopped. Push one end of the positive film (F). When the positive film F is introduced into the interior through the inlet 111, the entrance detecting unit 500 installed in the inlet 111 detects the entrance and exit of the positive film F to control the entrance detection signal 1500. Will output The control unit 1500 receiving the access detection signal from the entrance detecting unit 500 is to control the operation of the first transfer unit 800 and the second transfer unit 900, which will be described in more detail as follows. .

First, the first lifting unit 810 and the first driving unit 820 constituting the first transfer unit 800, the operation is controlled by the control unit 1500, in the case of the first lifting unit 810 The elevating block 811 is shot downward, and thus the first driving unit 820 installed in the first elevating unit 810 descends naturally, and in the case of the first driving unit 820, clockwise (see FIG. 7B). The shaft 821 and the roller 822 are also naturally rotated as it rotates. At this time, when the first driving unit 820 is lowered by the first elevating unit 810, a portion of the roller 822 penetrates through the hole of the back plate 130 and presses the upper surface of the positive film F while pressing. The positive film F is transferred along the longitudinal direction of the case body 110. For reference, the positive film F moved by the first driving part 720 is finally in contact with the inner (end) wall surface of the case body 110.

After the positive film F is transferred by the first transfer unit 800 as described above, the first transfer unit 800 is lifted up through the first lifting unit 810 controlled by the controller 1500. On the contrary, while the second transfer unit 900 is lowered, the positive film F is transferred to the end direction of the case body 110, which will be described in more detail as follows.

The operation of the second lifting unit 910 and the second driving unit 920 constituting the second transfer unit 900 is controlled by the control unit 1500, in the case of the second lifting unit 910 When the block 911 is shot downward, the second driving unit 920 installed in the second lifting unit 910 descends naturally, and in the case of the second driving unit 920 in a clockwise direction (see FIG. 7D). As it rotates, the shaft 921 and the roller 922 also rotate naturally. For reference, the positive film F moved by the second driving part 920 finally has a side end portion abutting the inner longitudinal wall surface of the case body 110.

The scanner 300 is operated and controlled by the control unit 1500 in a state where the positive film F is brought into contact with the inner wall of the case body 110 as described above, and the positive film is placed on the upper surface of the transparent plate 200 ( F) It reads like a copy and makes it into a file (numeric map). For reference, it is made into a file (numeric map).

On the other hand, the controller 1500 continuously receives the temperature measured by the temperature sensing unit 700, in which case, if the temperature measured from the temperature sensing unit 700 is higher than the preset reference value outputs the control unit 1500 controls the operation of the cooling unit 1200, the exhaust fan 1400, and the alarm means 1600.

First, in the case of the cooling unit 1200, the cooling unit 1200 operated by the control unit 1500 to supply the cool air to the cooling line 1100, the cold air moves along the cooling line 1100 In the process of being discharged through the cooling line 1100, the discharged cold air to cool the white plate 130, the cooled white plate 130 is gradually cooled the positive film (F) by the positive film (F) by the heat Since the deformation can be prevented, it is possible to obtain a precise image with little error from the positive film (F).

The positive film F having the heat seated on the transparent plate 200 by forcibly discharging the internal heat of the case body 110 to the outside while rotating together with the exhaust fan 1400 when the cooling device 1200 operates. Minimize the heat transfer to prevent thermal deformation caused by heat.

In addition, the alarm means 1600 receives an emergency signal from the control unit 1500 and generates a sound to inform the worker, and the worker can intuitively recognize the emergency situation through the sound to quickly follow up. .

On the other hand, when the temperature received from the temperature sensing unit 700 is lower than the predetermined reference value, the control unit 1500 is operated to stop the operation of the cooling unit 1200, the exhaust fan 1400 and the alarm means 1600. To control.

Referring to FIG. 8, on the other hand, when an operator opens and closes the cover 120 to generate a drawing image, the proximity detecting unit 600 exposed to the outside by the opening and closing cover 120 detects the worker to detect the proximity signal. The control unit 1500 outputs the control unit 1500, and the control unit 1500 receives the information and controls the ultrasonic wave generating means 1000.

In addition, the ultrasonic generating means 1000 operated by the controller 1500 generates a high frequency to output to the outside through the speaker 1020, through which the beetle (B) can no longer approach the fuser and other Fly to the place.

Therefore, the above-described action can prevent the damage of the drawing image due to the influx of the beetle (B) during the scanning process can not only obtain a more accurate drawing image, but also pests such as mosquitoes It is very practical because it also performs the function of exterminating pests.

When the file generation operation is completed, the control unit 1500 controls the second transfer unit 900 to transfer the positive film F along the end direction, and when the transfer of the positive film F is completed, the second The transfer unit 900 is lifted and at the same time the first transfer unit 800 is lowered, the first transfer unit (P) so that the positive film (F) can be withdrawn through the inlet 111 of the case body 110 ( Operation 800 is controlled to draw the positive film (F) to the outside.

When the operation is completed by rotating the opening and closing cover 120 of the fuser case 100, the protrusion 121 of the opening and closing cover 120 is coupled to be inserted into the fixing groove 114 of the case body 110, Due to the combination, as the button of the switch unit 400 is introduced into the inside, the power connection is naturally cut off.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100: fuser case 110: case body 111: inlet
112: support piece 113: injection pipe 114: fixed groove
120: opening and closing cover 121: protrusion 200: transparent plate
300: scanner 400: switch unit 500: access detection unit
600: proximity detection unit 700: temperature detection unit 800: the first transfer unit
810: first lifting unit 820: first driving unit 900: second transfer unit
910: second lifting unit 920: second driving unit 1000: ultrasonic generation means
1100: cooling line 1110: first connection 1120: cooling unit
1130, the second connection portion 1200: the cooling unit 1300: the compressor
1400: exhaust fan 1500: control unit 1600: alarm means
F: positive film B: beetle

Claims (1)

In the form of a box provided with a space therein, the inlet 111 is formed so that the positive film (F) on the one side, and protrudes inward along the inner surface to support the transparent plate 200 A piece 112 is formed, and the opposite side of the inlet 111 is formed with an injection pipe passage 113 interconnected with the compressor 1300 so that air can be injected toward the inlet 111. A case body 110 having a fixing groove 114 formed on both sides of the 111 to allow the protrusion 121 of the opening and closing cover 120 to be detachably fixed; With a protrusion 121 detachably coupled to the fixing groove 114 of the case body 110, the opening and closing cover 120 is rotatably installed in the case body 110 to open and close the inlet 111 ; The fuser case 100 which is internally installed in the case body 110 and has an opaque material white plate 130 spaced apart from an upper surface of the transparent plate 200:
Transparent plate 200 which is fixed to the support piece 112 so that the positive film (F) is seated on the upper surface:
Scanner 300 which is built in the case 100 to be disposed on the bottom surface of the transparent plate 200 reads the positive film (F) seated on the transparent plate 200 as a copy to make a file:
Switch unit 400 is installed on the case body 110 to be operated by the opening and closing cover 120 to control the power ON / OFF:
The entrance detection unit 500 is installed at the inlet 111 so as to detect the entrance and exit of the positive film F to output an entrance detection signal.
Proximity detection unit 600 is installed in the case body 110 adjacent to the switch unit 400 so as to detect an object that is close to output an object detection signal when detecting an object in proximity:
The temperature sensing unit 700 is installed between the white plate 130 and the transparent plate 200 of the fuser case 100 to detect an ambient temperature and output a temperature sensing signal:
A pair of lifting and lowering blocks 811, which are installed between the case body 110 and the back plate 130 and controlled by the control unit 1500, are used to raise and lower the lifting blocks 811. 1 lifting section 810; The control unit 1500 includes a shaft 821 rotatably inserted into the elevating block 811 of the first elevating unit 810 and a roller 822 inserted into and fixed to the circumferential surface of the shaft 821. The first transfer unit 800 is configured to be operated in the direction of the end of the case body 110, the operation control is configured to rotate the shaft 821 in the forward or reverse direction, the case body 110:
A pair of lifting and lowering blocks 911 are installed between the case body 110 and the back plate 130 and controlled by the controller 1500 to move the lifting block 911 up and down. 2 lifting parts 910; The control unit 1500 is provided with a shaft 921 rotatably inserted into the elevating block 911 of the second elevating unit 910 and a roller 922 inserted into and fixed to the circumferential surface of the shaft 921. The second transfer unit 900, which is configured to be operated in the longitudinal direction of the case body 110, the operation control is configured to rotate the shaft 921 in the forward or reverse direction.
An ultrasonic circuit board 1010 which is operated by the controller 1500 and generates a high frequency so that a high frequency can be output through the speaker 1020; Ultrasonic generating means (1000) consisting of a speaker (1020) which is operated by the ultrasonic circuit board 1010 to output a high frequency to the outside:
A first connection part 1110 whose one end is exposed to the upper surface of the case body 110 and the other end is in the case body 110; A cooling unit 1120 having one end communicating with the other end of the first connection unit 1110 and transferring cold air to the surroundings; Cooling line 1100 having one end connected to the other end of the cooling unit 1120 and the second end 1130 exposed at the other end to the upper surface of the case body 110:
The cooling device unit 1200 installed between the first connector 1110 and the second connector 1130 and operated by the controller 120 to supply cold air to the cooling line 1100:
Compressor 1300 installed in the case body 110 and connected to the injection pipe line 113 and operated by the controller 1500 to supply air to the injection pipe line 113:
Exhaust fan 1400 installed in the case body 110 and operated by the control unit 1500 to forcibly discharge the internal heat to the outside:
Receiving power from the switch unit 400 to control the operation of the compressor 1300, and receives the entrance detection signal from the entrance detection unit 500, the first transfer unit 800, the second transfer unit 900 and the scanner ( 300 sequentially controlling the operation, receiving the object detection signal from the proximity sensing unit 600, and outputs the operation signal to the ultrasonic circuit unit 1010 so that the ultrasonic wave is output through the speaker 1020, the temperature sensing unit 700 Control unit 1500 for outputting an emergency signal while operating the cooling unit 1200 and the exhaust fan 1400 when the temperature detection signal is received from the reference value exceeds:
Precision drawing device for improved stability, characterized in that it comprises an alarm means 1600 for generating a sound by receiving an emergency signal from the control unit 1500.

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