JPH03254879A - Dewatering dryyer - Google Patents

Abstract

PURPOSE:To perfectly remove waterdrops turning to the rear by successively arranging a cap part waterdrop blow-off mechanism, a shoulder and body part waterdrop blow-off mechanism and a bottom part waterdrop blow-off mechanism in a continuous transfer direction. CONSTITUTION:An object (b) to be dewatered and dried being a perfusion bottle is transferred to the feed conveyor 2 of each of respective lines 8, 9 in such a state that waterdrops are bonded to the rear thereof and held by plastic chains 39a, 39b to be continuously transferred. The waterdrops bonded to the cap part mouth of the bottle are scattered by the compressed air downwardly blown out toward the top part of the bottle from the downward nozzle 11 of a cap part waterdrop blow-off mechanism 3 and the compressed air blown out an both sides of the bottle from the lateral blow-off orifices 12, 12... of left and right nozzles 13, 14. Further, compressed air is blown against the single surface of the bottle from a single surface-forcible blow-off mechanism part 25 and also blown against the other single surface thereof from an other single surface-forcible blow-off mechanism part 26. By this method, waterdrops are blown off in a highly efficient manner.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention is a water removal drying method in which water droplets adhering to the outer surface of a dried object such as a plastic bottle are forcibly blown off by pressurized air. This is a device that forcibly removes water droplets attached to the surface of plastic infusion bottles filled with infusions and transported after the sterilization process to support subsequent inspections, packaging processes, etc. This water removal/drying device is suitable for use in cases where it is desired to prevent water from occurring.

(Prior art) In the production line equipment for infusion bottles, which are made by filling plastic bottles with infusions and welding and tightening the caps, a continuous sterilization process is performed after the filling process of filling the plastic bottles with infusions and tightening the caps. After this continuous sterilization process, the surface of the plastic bottle is wet due to the cooling water or washing water, in other words, it has water droplets attached to it, so the inspection following the continuous sterilization process,
In order to ensure that the integrated manufacturing equipment of the infusion bottle production line operates smoothly and efficiently, it is necessary to remove and dry the water droplets that adhere to the surface of the glass bottle during the sterilization process. is necessary.

Therefore, when using hot air drying, the drying temperature must be 50°C or lower, since the plastic bottle is relatively thin and the body is gradually constricted during infusion to prevent the plastic bottle from deforming. At this temperature, a 500 ml infusion bottle would take more than 30 minutes to dry, and if it were to be used in a continuous production line, the scale of the equipment would be large and the equipment costs would be enormous. be.

In addition, conventional methods for removing water and drying using pressurized air can be used, for example, by providing a vertical slit in the softening box as a means to remove moisture adhering to the surface of the product by jetting room temperature air, and air at room temperature is blown out from the vertical slit. A means for blowing air from a direction perpendicular to the direction of transport onto the dry body to be removed, which is being transported by a conveyor, or pressurized air introduction pipes are installed in parallel, and blowing holes are provided in opposing parts of each of these pressurized air introduction pipes. There is a means of providing a plurality of blow holes in a straight line in the horizontal direction and simultaneously blowing room temperature air from both sides of the dry body to be water removed from a group of these blow holes.

According to such means, as a result of conducting tests and research,
In the case of plastic bottles that are flat, that is, the body is smaller in thickness than the width, when pressurized air is blown onto the bottle, water droplets attached to the surface of the bottle wrap around to the back side, causing repeated application. Even by blowing compressed air, water could not be completely removed.

Under these circumstances, the inventor of the present invention conducted extensive research on how to remove water and dry in a short time without increasing the scale of the equipment, and as a result, adopted the method of blowing pressurized air. In addition, we have developed a device that is ideal for a continuous, integrated manufacturing line for filling and packaging infusion bottles, which are dried water-removed bodies.

(Problem to be Solved by the Invention) When trying to remove water droplets adhering to the surface of a plastic bottle by blowing pressurized air, the problem is that the water droplets wrap around the back side and cannot be completely removed. was there.

(Means for Solving the Problems) The present invention is such that water droplets are forced to fall off gradually from the upper part as the water-removed dry body is continuously transferred,
1) A cap part water droplet blowing mechanism that sprays compressed air toward the upper end of the dry body to be removed along the continuous transport direction to feed the dry body to remove water, and a water droplet blowing mechanism at the cap part that scatters water droplets. Shoulder part that blows high-pressure air from a downward diagonal direction toward the torso alternately on one side and the other side, shifting the position in the continuous transport direction, a torso water droplet blowing mechanism, and a hanging support. A water removal/drying device is characterized in that a bottom water droplet blowing mechanism for blowing pressurized air toward the bottom of a dried object to be water removed that is in a state is disposed sequentially in the traveling direction of a continuous transfer direction, Item (2) faces the conveyor conveying the dry body to be removed, and has a downward nozzle, a left nozzle, and a right nozzle, and blows compressed air toward the upper end of the dry body to scatter water droplets. A cap part water droplet dropping mechanism, and next to this cap part water droplet dropping mechanism, on the opposite side of the conveyor and shifted in the transfer direction, alternately downward toward the shoulder and body of the dry object to be water removed. Pressurized air is blown from an oblique direction in the traveling direction from a group of blow-off holes arranged in a downward direction and a group of horizontal blow-offs, forming a forced blow-off mechanism on one side and a forced blow-off mechanism on the other side. A blow-off mechanism, and a suspension conveyor that is next to the water drop blow-off mechanism on the shoulders and body, suspend the dry body to be removed, and shift the pressurized air from both sides toward the bottom in the transfer direction. A bottom mechanism that prevents water droplets from falling and floating up, and a body that blows pressurized air from one side to the other side by shifting the position in the transfer direction.
A water removal drying device is characterized in that a bottom water drop spraying mechanism is sequentially provided, and claim (3) is a water removal drying device characterized by sequentially providing a bottom water droplet spraying mechanism, and claim (3) is a water removal drying device characterized in that a downward nozzle and a left nozzle are provided at the starting end (1ll side) of a conveyor for feeding the dried material to be removed. A cap part water droplet blowing mechanism consisting of a right-hand nozzle and a cap part water droplet dropping mechanism is provided, and a hanging conveyor that suspends the water removal dry body in a hanging manner is placed next to the cap part water droplet blowing mechanism. A shoulder part, a body part consisting of a forced blow-off mechanism part on one side having a group of blow-off holes and a group of horizontal blow-off holes that blow pressurized air from a downward diagonal direction toward the body part, and a forced blow-down mechanism part on the other side. A water droplet blow-off mechanism is provided, and after this shoulder and body forced blow-off mechanism, the water droplet is removed from the downward diagonal direction and the horizontal direction toward the body and bottom of the dry body to be removed, which is suspended by the suspension conveyor. A body and a bottom water droplet spraying mechanism are provided to spray pressurized air, and pressurized air is alternately sprayed toward the bottom from the opposite side of the body and the bottom waterdrop spraying mechanism by shifting the position in the transfer direction from the opposite side. Equipped with a mechanism to prevent water droplets from falling and rising at the bottom.
Next to this bottom water droplet blow-off/fly-up prevention mechanism, a body and bottom water droplet blow-off mechanism is provided, which is composed of a group of downward diagonal blow-off holes and a one-sided spraying section that sprays pressurized air, and another one-sided spraying section. This is a water removal drying device characterized by the following.

(Function) The upper end of the cap, etc. of the dried body to be water removed is blown away by compressed air, and then compressed air is sprayed downward and diagonally from the opposite side to the neck and torso alternately at slightly different times. The water droplets adhering to the surface are forcibly blown off, and the water droplets adhering to the outer surface of the bottom are forced down by pressurized air that is blown horizontally against the bottom of the drying object. The water droplets are removed, and water droplets are prevented from flying up, and then they are reliably dried by pressurized air.

(Example) An example of the water removal drying device according to the present invention will be described in detail.

Referring to FIGS. 1 and 2, the water removal drying device 1 sequentially moves water droplets from the cap portion from the left to the right along the continuous transfer direction (a) of the conveyor 2 serving as a continuous transfer path. Drop-off mechanism 3, shoulder and torso water drops I! A water droplet spraying mechanism 6 is provided on the treetop 4, the bottom part of the water droplet spraying mechanism 5, and a water droplet spraying mechanism 6 on the body and bottom part. 4. Mechanism to prevent water droplets from falling and rising at the bottom 5.
In this example, the line equipment consisting of the body part and bottom water droplet blowing mechanism 6 is provided as a two-system line equipment, and these two systems are installed in the processing chamber 7.
System lines 8 and 9 are installed in parallel.

As shown in FIG. 1, FIG. 5, FIG. 6, FIG. 7, FIG. 8, and FIG.
A downward nozzle 11 having a plurality of downward blowing holes 10,10... in a row, and a left nozzle 13 and a right nozzle 14 having horizontal blowing holes 12,12... are provided.
As shown in Figs. do,
A downward nozzle 11, a left nozzle 13, and a right nozzle 14 are arranged, and in particular, the blowing holes 1 of the left nozzle 13 and the right nozzle 14 are arranged.
2.12... are arranged in vertical rows, and the lowest blow-off holes 12a are designed to blow downward and diagonally toward the shoulder of the infusion bottle.

As shown in FIGS. 1 and 4, the shoulder and body water drop blowing machines 4 are arranged alternately on opposite sides along the transport conveyor 2 and with their positions shifted in the transport direction, respectively, to blow off boxes 15. , 1617.18, 19.20 are arranged, and these cooking boxes 15, 16, 17, 18.19゜2
0, as shown in FIGS. 15 and 16, has a pressurized air introduction #I21, and a continuous transfer direction ( Along a), the air outlet holes 23a to 23Q at the starting end are arranged in a gradually descending straight line, and then the air outlet holes 24a to 24e from the air outlet hole 24a to the air outlet hole 24et at the end are arranged in a horizontal straight line. In addition, the blow-off holes 23a to 23 have downwardly slanted blow-off holes, and in this example, as shown in the drawing, the downward angle (α) is 3Q degrees, and the downward linear inclination angle (β) is 3Q degrees.
is set at 15 degrees, the blow-off holes 24a to 24e are horizontal blow-off holes, and the shoulder and body water droplet blowing mechanisms 4 face the continuous transfer direction (a) as shown schematically in FIG. 17. On the opposite side, a one-sided forced blow-off mechanism section 25 and another one-sided forced blow-off mechanism section 26 are arranged alternately and shifted in position in the continuous transfer direction.

The mechanism 5 for preventing water droplets from falling off and rising from the bottom is shown in FIGS. 1 and 4.
18 and 19, blow-off boxes 27 and 28 are arranged near the end of the conveyor 2, slightly spaced apart from the blow-off box 20 in the traveling direction, and shifted in position in the transport direction. Yes, there are multiple balloon boxes 27° and 28 placed horizontally at the bottom! ! It has lower air outlets 29, 29, 29 arranged in the form of horizontal slits, and has an upper air outlet 30 in the form of horizontal slits that blows out pressurized air diagonally downward and prevents water droplets from flying up. Has a speech bubble box 2
A bottom water droplet prevention mechanism 5 is formed from a mechanism section 31 on one side including the blowout box 28 and an 88 section 32 on the other side including the blowout box 28. The conveyor 2 is not extended in the area where the conveyor 2 is provided.

As shown in FIG. 1, the body and bottom water droplet dropping mechanisms 6 are
Blowout boxes 33 and 34 are disposed next to the bottom water dripping and floating prevention mechanism 5, and are disposed on the opposite side of the continuous transfer path and shifted in position along the transfer direction (a), On the front wall portion 35 of these blowout boxes 33 and
As shown in FIG. 0 and FIG. 21, the air outlet 36a at the starting end
The blow-off holes 36a to 36s from
6a to 36s are downward oblique blow-off holes, and in this example, as shown in the drawing, the downward angle (γ) is 30 degrees, and the downward linear inclination angle (δ) is 15 degrees.

Therefore, the body and bottom water droplet machines [6 are in the continuous transfer direction (a
), and consists of a one-sided forced blow-off mechanism part 37 and an other-side forced blow-off mechanism part 38 on the opposite side and shifted in position in the continuous transfer direction.

At the top 3 of the cap part water droplet blowing machine, a conveyor 2 is installed.
In order to hold the infusion bottle as the dried water to be removed (a) and to prevent it from interfering with the blowing of compressed air,
As shown in the figure, the infusion bottle is held and transferred by plastic chains 39a and 39b that rotate horizontally and are placed on both sides. In this case, a sensor (not shown) detects the infusion bottle and blows compressed air intermittently.

In the side 4 of the shoulder and body water droplet blowing machine, there are one-sided forced blowing mechanism parts 25 arranged alternately at the rear end and the other one-sided forced blowing mechanism part 26 to prevent water droplets from falling off and flying up from the bottom part. Mechanism 5
A suspension conveyor 40 is attached to this area, which suspends the infusion bottle in a hanging manner and continuously transports it.As shown in FIG. The infusion bottle is hung by the hooks 4343 attached to the rotating chenos 41 and 42, respectively, which touch the flange (c) of the filling opening of the infusion bottle from below. The lower part of the infusion bottle, which has been suspended in this way, is released and transported in a suspended state, and even at the bottom part of the mechanism 5 for preventing water drops from falling and floating up, the infusion bottle is suspended in the air by the suspension conveyor 40. Pressurized air is blown toward the bottom to prevent water droplets from flying up.

In the body and bottom water droplet blowing machine 1116,
Pressurized air is alternately blown onto each side of the infusion bottle while being transported by the suspension conveyor 40, and the infusion bottle that has passed through the body and bottom water droplet blowing mechanisms 6 is transferred from the suspension conveyor 40 to the conveyor. 44, and is discharged to proceed to the next process.

In FIGS. 1 and 2, reference numeral 45 is an exhaust duct;
46 is an air suction port.

In this example, the infusion bottle as the dried water body (a) to be removed is shown in Figs. 10, 11, 12, 13, and 14.
The hook shown in the figure has a ring portion (d) on the outer bottom surface of the hook for hanging the infusion bottle upside down, and the infusion bottle is transferred with its width direction along the continuous transfer direction (a).

The present invention is constructed as described above and operates as follows.

After the infusion bottle as the dry body to be water removed (a) is filled with infusion liquid from the filling port into the container body, the cap is welded and tightened, and the bottle is introduced into the sterilization process and is passed through each line 89 with water droplets attached to the back side of the infusion bottle. conveyor 2, and is held by plastic chains 40a, 40b from both sides near the starting end of the conveyor 2 and continuously transported (the fifth
(See figure) Cap water droplet dropping mechanism 3 (Figures 1 and 7)
Compressed air blows out downward from the downward nozzle 11 (see figure) toward the top, and compressed air blows out from both sides through the horizontal blow-off holes 12, 12... (see figure 8) of the left nozzle 13 and right nozzle 14. As a result, water droplets adhering to the cap part (b) are scattered.

Next, pressurized air is blown onto one side of the infusion bottle, which is continuously transferred on the transport conveyor 2, from the single-sided forced blow-off mechanism section 25 at the left end of the shoulder and body water drop blow-off machine treetops 4, so that the infusion bottle is continuously transported on the conveyor 2. As the infusion bottle moves along the conveyor 2, pressurized air is eventually blown onto the other side by the other side forced blow-off mechanism section 26, and in this way, the infusion bottle is not continuously transferred on the conveyor 2, so that one side and the other side are Pressurized air is blown alternately with the sides and at positions slightly shifted in the direction of travel in the continuous transport direction (a).

At this time, the blow-off holes 238 to 2 of the blow-off boxes 15 and 16 of the forced blow-off mechanism section 25 on one side and the forced blow-off mechanism section 26 on the other side are
From 3Q, 24a to 24e, the fluid is sprayed in a descending manner from the shoulder to the body of the infusion bottle, which advances sequentially along the continuous transport direction <a). In other words, pressurized air is blown downward from the shoulder of the infusion bottle to the body, forcing water droplets to fall from the top to the bottom, and eventually,
Water droplets adhering to the lower part of the body are also blown off by the pressurized air blown out in the horizontal direction from the blow-off holes 24a to 24e (see FIG. 23).

Next, the infusion bottle is transferred from a hanging state to a suspended state by a hanging conveyor 40.

That is, as shown in Fig. 20, the infusion bottle is hung in such a way that the hooks 43 and 43 of the horizontally rotating chenos 41 and 42 placed on both sides lift the brim (C) from below.
An infusion bottle suspended in the air and transported along the continuous transport direction (a) in a downwardly released state is blown with pressurized air on one side and then on the other at positions slightly shifted from the direction of travel, causing water droplets to be blown off. Ru.

Subsequently, when the infusion bottle is transferred in a suspended state and advances to the position of the bottom water droplet prevention mechanism 5, pressure is blown out from the lower outlet 29, 29.29 of the outlet box 27.28. Air is blown, and the water droplets adhering to the bottom are further blown down, and the pressurized air is blown diagonally downward from the upper outlet 30, forming an air curtain shape, causing the water droplets to fly up. Prevented.

The outer bottom of the infusion bottle in this example is provided with a ring part (D) for hanging the infusion bottle upside down. The hook is efficiently blown off by water droplets on the ring part.

Next, when the infusion bottle being transported in a suspended state passes through the body and bottom water droplet blowing mechanism 6, pressurized air is blown on one side and the other side to remove water and dry it, and in this way, the surface is The sufficiently and reliably dried infusion bottles are sequentially transferred from the end of the hanging conveyor 40 to the carry-out conveyor 44,
Move on to inspection and packaging process.

Note that the pressure and air volume of the pressurized air blown out from the blow-off holes and blow-off ports are appropriately selected in consideration of the size, shape, etc. of the dry body to be water removed.

In addition, the downward angles (α) and (γ) of the downward blowing holes were set to 30 degrees in this example, and the water was sprayed downward onto the surface of the dry body to be removed. ) is within the range of 15 degrees to 80 degrees, depending on the size, shape,
It is desirable to set the angle in consideration of the state of water droplet adhesion, etc., and to set the angle smaller than 15 degrees to a larger angle of 80 degrees.

(Effects of the Invention) The present invention provides water to be removed by scattering water droplets adhering to the cap part, distributing the water droplets in a descending manner sequentially from the starting end, and continuously transferring pressurized air blown diagonally downward from the blow-off hole. one side of the dry body,
The water is sprayed alternately with the other side and sequentially from the top to the bottom so as not to interfere with each other, and water droplets that try to go around to the other side by spraying from one side are blown off by spraying to the other side.
Water droplets that try to go around to one side by spraying from the other side are blown off by spraying to one side, so the water droplets are blown off with high efficiency.

In addition, pressurized air is sprayed sequentially from the top to the bottom, diagonally downward, and then from the horizontal direction.
It is possible to further encourage water droplets to blow off from the other side.

Furthermore, pressurized air is blown horizontally from both sides toward the bottom of the dry body to be water removed, which is suspended in the air, and the water droplets at the bottom are further blown off. By spraying this, the surface of the dry body to be water removed is sufficiently and reliably dried, and the work in the next process is not hindered.

[Brief explanation of drawings]

Fig. 1 is a plan view showing an outline of the device of the present invention, and Fig. 2 is a plan view showing the outline of the device of the present invention.
3 is an end view as seen from the right end side, FIG. 4 is a schematic explanatory diagram showing the main parts of the device of the present invention as seen from the TV-TV line in FIG. 1, and FIG. A sectional view of the main part of the water droplet spraying mechanism of the cap part corresponding to the line v-v in the figure, FIG. 6 is a sectional view of the main part of the mechanism part that suspends the dry body to be removed, and FIG. A schematic explanatory diagram of the blow-off holes of the downward nozzle in the dropping mechanism, Fig. 8 is a schematic explanatory diagram of the blow-off holes of the left nozzle and right nozzle, and Fig. 9 is a cross-section of the main part corresponding to the IX-IN line in Fig. 8. Figure 10 is a front view of the infusion bottle as a dry body to be removed, Figure 11 is a side view, Figure 12 is a plan view, Figure 13 is a sectional view of the body, and Figure 14 is a side view of the infusion bottle. The figure is a bottom view of the same, and FIG. 15 is a front view showing the arrangement positions of the air outlet of the shoulder, one side of the body water droplet blowing mechanism, and the outlet box of the other side of the water droplet blowing mechanism. Figure 16 is the 15th
A sectional view taken along the line XVI-XVI in the figure, FIG. 17 is an explanatory diagram of the main parts of the shoulder and body water droplet blowing mechanisms, and FIG. 18 is a front view of the 5tys blowout box that prevents water droplets from falling and flying up at the bottom.
Fig. 19 is a sectional view of the main part of the same, Fig. 20 is a front view showing the arrangement of the air outlet of the air outlet box of the body and bottom water droplet blowing mechanism, and Fig. 21 is a sectional view taken along XXI-XXIM in Fig. 20. FIG. 22 is a sectional view of a main part of a hanging conveyor that carries out suspended conveyance, and FIG. 23 is an explanatory view of the state of spraying from the outlet holes in the shoulder and body water droplet spraying mechanisms. 1...Water removal drying device, 2...Transportation conveyor, 3.
...Water droplet falling mechanism on the cap part, 4...Water droplet falling mechanism on the shoulder and body parts, 5...Mechanism for preventing water droplets from falling off and floating up on the bottom part, 6.
. . . Body, bottom water droplet dropping mechanism, 7. Processing chamber, 8.
9 lines, 10...Downward blowing hole, 11...Downward nozzle, 12...Sideward blowing hole, 13...Left nozzle, 14...Right nozzle, 15,16.1718.19,
20, 27, 28, 33. 34... balloon box,
23a~23Q 24a~24e, 36a~36s...
・Blowout hole, 25.37... Single side forced blowdown mechanism part, 26
．． 38...Other side forced blow-off m#1 part, 29...Lower outlet, 30...Upper outlet, 31...One side am part, 3
2...Other single-sided mechanism section, 40...Hanging conveyor, 4
1.42...cheno, 43...hanging tool, 44...
Unloading conveyor, (a)...Water removed dry body, (b)...
...Cap part, (c)...Brim part.

Claims (8)

[Claims] (1) A cap part water droplet blowing mechanism that sprays compressed air toward the upper end of the dry body to be removed and scatters water droplets along the continuous transfer direction of the dry body to be removed; The shoulder part, which blows pressurized air from a diagonal downward direction alternately on one side and the other side toward the body part, and with the position shifted in the continuous transport direction, and the body part have a water droplet blowing mechanism, and a hanging mechanism. A water removal/drying device characterized in that a bottom water droplet blowing mechanism for blowing pressurized air toward the bottom of a dried object to be water removed in a holding state is sequentially disposed in the traveling direction of a continuous transfer direction. (2) Facing the conveyor that feeds the dried water to be removed,
A cap part water droplet blowing mechanism that has a downward nozzle, a left nozzle, and a right nozzle and blows compressed air toward the upper end of the dried water object to scatter water droplets, and next to this cap part water droplet blowing mechanism, and a group of blow-off holes arranged on the opposite side of the transport conveyor and shifted in the transport direction so as to alternately blow pressurized air from a downward diagonal direction toward the shoulders and body of the dried object to be water-removed in the direction of travel; A shoulder and body water droplet blowing mechanism consisting of a forced blowing mechanism on one side and a forced blowoff mechanism on the other side that spray from a horizontal blowing group, and a mechanism next to and suspended from the shoulder and body water droplet blowing mechanisms. A mechanism for preventing water droplets from falling off and floating up at the bottom is used to hold the dry body to be removed on a conveyor and blow pressurized air toward the bottom alternately from both sides at different positions in the transport direction. A water removal drying device characterized in that a body section for blowing pressurized air on one side and another side, and a water droplet blowing mechanism at the bottom are sequentially provided. (3) A cap water droplet spraying mechanism consisting of a downward nozzle, a left nozzle, and a right nozzle is installed near the starting end of the conveyor that feeds the dried material to be removed. A group of blowing holes and horizontal blowing holes that blow pressurized air from a downward diagonal direction toward the shoulders and body of the dry dried object to be water-removed, which is suspended by a hanging conveyor. A shoulder and body water droplet blowing mechanism is provided, which includes a forced blowing mechanism on one side and a forced blowdown mechanism on the other side. The body of the dry object to be removed is suspended by the body, the body blows pressurized air toward the bottom from a downward diagonal direction and the horizontal direction, and a bottom water droplet blowing mechanism is provided. A bottom water droplet falling/flying prevention mechanism is provided which alternately blows pressurized air toward the bottom by shifting the position in the transfer direction from the opposite side. 1. A water removal drying device characterized in that a body part consisting of a group of downward diagonal blow-off holes and a one-sided blowing part for blowing pressurized air and the other one-sided blowing part, and a bottom part water droplet blowing mechanism are provided. (4) The downward angle of the downward diagonal blow-off hole of the shoulder and body water droplet blowing mechanisms, the one-sided forced blow-off mechanism part of the body and bottom water droplet blow-off mechanism, and the downward diagonal blow-off hole of the other one-sided forced blow-off mechanism is set to 30 degrees. The water removal drying device according to any one of claims (1), (2), and (3), characterized in that: (5) The water removal drying device according to claim (4), wherein the downward angle of the blowing hole from the downward diagonal direction is 15 degrees to 80 degrees. (6) The blow-off holes of the one-sided forced blow-off mechanism section of the shoulder and body water drop blow-off mechanisms, and the blow-off box of the other one-side forced blow-off mechanism section are arranged at the starting end along the continuous transport direction of the dried water to be removed. The group of blow-off holes from the blow-off hole to the end blow-off hole is gradually arranged in a descending manner, and the pressurized air is directed to the one side blowing section and the other side blowing section facing the continuous transfer direction and on the opposite side in the continuous transfer direction. The water removal drying device according to any of claims (1), (2), and (3), characterized in that the water removal drying device is provided at a position shifted from the water removal drying device. (7) The blow-off holes of the blow-off boxes of the one-side spraying part and the other-side spraying part of the water droplet blowing mechanism of the body and shoulder parts are used to blow out an intermediate direction from the blow-off hole at the starting end along the continuous transfer direction of the dried water to be removed. The holes are arranged in a descending manner gradually, and then from the intermediate direction change blow-off hole to the end blow-off hole are arranged horizontally, and the blow-off holes from the start end blow-off hole to the middle blow-off hole are arranged for pressurized air. The water is blown out diagonally downward from one side of the dry body to be removed, the air outlet from the intermediate outlet to the terminal outlet is a horizontal outlet, and a forced blow-off mechanism part on one side and a forced blow-off mechanism part on the other side are provided. Claims (1), (2), and (3) are characterized in that they are provided facing the continuous transport direction, on the opposite side in the continuous transport direction, and alternately arranged with shifted positions in the travel direction. Water removal drying equipment. (8) The bottom water droplet prevention mechanism includes a one-sided mechanism part and another one-sided mechanism part, and each of these one-sided mechanism parts and the other one-sided mechanism part is arranged in a plurality of horizontal rows at the bottom of the blow-off box. It has a horizontal slit-shaped lower outlet arranged at the top and blows out pressurized air horizontally, and a horizontal slit-shaped upper outlet arranged at the top and blows out pressurized air diagonally downward. The water removal dryer according to claims (1), (2), and (3), wherein the mechanism section and the other single-sided mechanism section are alternately arranged on opposite sides of the continuous transfer path with their positions shifted in the transfer direction. Device.