KR20110015681A - A laver dehydrating device - Google Patents

Abstract

The present invention provides a dehydration time extension dehydration apparatus. The apparatus includes an upper dehydration beam, a lower dehydration beam, and a powertrain used for causing movement in a direction opposing or oriented the upper and lower dewatering beams, the powertrain including a link rod. The dewatering device further includes a support, a lock adjusting member and an upper dewatering beam position limiting member, wherein the support is installed at the end of the upper dewatering beam and has a through hole and the first end of the link rod extends through the through hole of the support. On the other hand, it moves in the through hole of this support within a certain range, and the lock adjustment member is provided in the link rod. The apparatus may further include a dehydration time extension member or the dehydration time extension member may be a press spring assembly. The dehydration apparatus of the present invention can extend the dehydration time and squeeze out the moisture generated in the floating seaweed in the seaweed herbicide process to the maximum and shorten the drying time of the floating seaweed to realize the technical effect of energy saving and consumption reduction.

Description

Dehydration time extension dehydration apparatus used in dehydration stage of laver primary processing unit {A LAVER DEHYDRATING DEVICE}

The present invention relates to the field of laver processing, and more particularly, to a dehydration time extension dewatering apparatus used in the dehydration step of the laver primary processing unit. The dehydration apparatus according to the present invention can extend the compression dehydration time and squeeze the moisture generated in the floating seaweed in the seaweed herbicide process to the maximum and shorten the drying time of the floating seaweed to realize the technical effect of energy saving and consumption reduction. .

In general, the manufacturing process of laver primary processing is as follows.

The sub process is as follows.

Raw grass collection → (Handling out foreign materials manually →→ Raw cleaning → Automatic removal of foreign materials → Cleaning after dehydration → Dewatering after mixed washing → Dehydration of laver, steam and water proportional mixing (concentration initial adjustment) → Concentration precision adjustment → Main unit main process.

The main process of the main unit is as follows.

(Cleaning of foot) → Herb laver (floating laver) → Floating two stages of dehydrated laver → Drying and molding → Paper pre-separation of paper lamination → Paper lamination and lamination of paper lamination → Bonding, grading, redrying, and packing.

Floating seaweed dehydrator is an important part of the seaweed primary processing process, and dehydration effect directly affects the elevation of energy consumption indicator of the unit. One.

1A and 1B, the configuration and operation principle of a conventional floated dewatering device will be described in detail.

1. Basic configuration of the conventional floating dehydration device

1A and 1B show the basic configuration of a conventional floating dehydration apparatus. 1A is a structural diagram of a conventional floating seaweed dewatering device, and the dewatering sponge of the seaweed dewatering device floated in FIG. 1A is in an open state, but the dewatering sponge of the seaweed dewatering device floated in FIG. 1B is in a closed state. 1A and 1B, reference numeral 1 denotes an upper dewatering beam, numeral 2 an upper dehydration sponge, numeral 3 a lower dehydration sponge, numeral 4 a lower dehydration beam, numeral 5 a side plate of a frame, and numeral 6 Silver foot frame, 7 is knuckle bearing, 8 is tension bar, 9 is working bearing, 10 is eccentric wheel shaft, 11 is eccentric cam.

2. Working principle of the conventional dehydration device

It should be explained here that, for the sake of simplicity and clarity, only half of the structure of the dehydration part is shown in FIGS. 1A and 1B. 1A and 1B, one frame side plate 5 is provided on both left and right sides of the frame, and the upper dewatering beam 1 and the lower dewatering beam 4 are provided on the frame. An eccentric cam 11 is installed at the lower part of the frame, and the eccentric cam can be rotated by a drive of an electric mechanism (not shown). The eccentric cam 11 is provided with one eccentric wheel shaft 10. . A lifting lug is installed at the bottom of the lower dewatering beam 4, and an action bearing 9 is installed on the lifting lug, and the action bearing 9 rotates when the eccentric cam 11 is driven. Is driven to move along the up and down direction. A knuckle bearing 7 is installed on the side plate of the upper dehydration beam 1, and the knuckle bearing 7 may be fixedly connected to the tension bar 8 by, for example, screwing, and the other end of the tension bar 8 may be, for example. For example, the knuckle bearing may be fixedly connected by screwing. This knuckle bearing is connected with the eccentric wheel shaft 10 on the eccentric cam 11. When the eccentric cam 11 is rotated by the drive of the electric mechanism, the eccentric cam 11 rotates by interlocking the eccentric wheel shaft 10 thereon and the eccentric wheel shaft 10 is the knuckle bearing 7 and the tension bar. By (8), the upper dehydration beam 1 is interlocked so as to move along the vertical direction.

In addition, the upper dewatering sponge 2 is provided on the upper dewatering sponge 1, and the lower dewatering sponge 3 is provided on the lower dewatering sponge 4. The upper and lower dewatering sponges perform compression dehydration on the floated steam when the frame 6 moves up to the position of the upper and lower beams. The exercise mode of the foot frame 6 is an intermittent stepping motion and when the dewatering sponges 2 and 3 are separated, the foot frame moves in one working position and performs dehydration once and operates in this manner.

Below, the operation method of the conventional floated dehydration apparatus is demonstrated.

When the eccentric cam 11 is rotated by the drive of the electric mechanism, the eccentric wheel shaft 10 installed in the eccentric cam 11 rotates according to the rotation of the eccentric cam 11 and the eccentric wheel shaft 10 has rotated to the top dead center. As shown in Fig. 1A, this tends to be a downward motion. At this time, the upper dewatering beam 1 is located at the highest position and when the eccentric wheel shaft 10 continues to rotate, the eccentric wheel shaft 10 is applied to the acting bearing 9, the tension bar 8 and the knuckle bearing 7. By interlocking the upper dewatering beam (1) to the downward motion. At the same time, in the rotation process of the eccentric cam 11, the eccentric cam causes the upward movement by interlocking the lower dewatering beam 4 by the action bearing 9 installed on the lower dewatering beam 4. This realizes the opposing movement of the upper and lower dewatering beams. When the dehydration sponge provided at the bottom of the upper dehydration beam 1 and the foot on the footrest frame 6 are joined, the dewatering sponge installed at the top of the lower dewatering beam 4 is also joined to the lower surface of the foot. As indicated in, the upper and lower dehydration beams squeeze the floating laver on the foot and squeeze out the moisture in the laver. Thus, the water | moisture content of the seam which floated by the opposing compression or mutual compression of the up-and-down beam can be discharged | emitted.

As can be seen from the above, the conventional floating seaweed dewatering device adopts a structural pattern in which vertical beams driven directly by cam and link rods are mutually combined, and the dewatering time and the running speed of the unit maintain an unchanged proportional relationship. . However, the invariant proportional relationship between the dehydration time and the running speed of the unit is not suitable for the demand for dehydration of different seaweed quality or different seaweed herbicide operating conditions. Inevitably, dehydration does not occur and dry energy consumption increases. For this reason, it is very necessary to develop a self-driving dewatering device which is capable of extending the dehydration time.

The present invention proposes a dehydration device or a dehydration time extension dewatering device having a dehydration time extension function in consideration of the fact that the dehydration time of the conventional floating seaweed dehydration device is constant (when the running speed is unchanged). The so-called <dehydration time extension> mainly means effective control over the compression dehydration time of the floated seaweed while extending the dewatering time of the floated seaweed. The dehydration time extension dewatering device according to the present invention can extend the dehydration time of the laver to a certain extent while realizing effective control over the dehydration time, and the dehydration amount of different seaweed quality or different seaweed herbicide operating conditions. May be suitable for different demands. Therefore, it achieves the purpose of improving the dehydration rate of the water of the floating seaweed, shortening the drying time of the floating seaweed, saving energy, reducing consumption and improving the operating efficiency.

The present invention provides a dehydration time extension dehydration apparatus. The apparatus includes an upper dehydration beam, a lower dehydration beam, and a power mechanism used to cause movement in a direction opposing or oriented the upper and lower dehydration beams, wherein the power mechanism includes a link rod and the dewatering device. The support further includes a support, a lock adjusting member, and an upper dewatering beam position limiting member, wherein the support is installed at an end of the upper dewatering beam and has a through hole, and the first end of the link rod extends through the through hole of the support. Meanwhile, the lock adjusting member is moved to the link rod in the through hole of the support within a predetermined range.

In the dehydration time extension dewatering device according to the present invention, the power mechanism further comprises an eccentric wheel and an eccentric wheel shaft installed in the eccentric cam and the second end of the link rod and the eccentric wheel shaft on the eccentric cam via the knuckle bearing; Are interconnected.

In the dehydration time extension dewatering device according to the present invention, the eccentric cam interacts with the acting bearing installed in the lower dewatering beam and can transmit power to the lower dewatering beam through the acting bearing. It is driven in to move along the up and down direction.

In the dehydration time extension dewatering apparatus according to the present invention, the upper dewatering beam position limiting member is an adjustable position limiting bolt installed on the lower dewatering beam or on the side plate.

In the dehydration time extension dewatering device according to the present invention, the lock adjusting member is a lock adjusting nut.

In the dehydration time extension dewatering device according to the present invention, the dewatering beam and / or lower dewatering beam guide member further comprises a guide member guides the upper dewatering beam and / or lower dewatering beam in a direction facing each other or oriented It is used to move along.

In the dehydration time extension dewatering device according to the present invention, the guide member includes a guide bar and a guide bearing, the guide bar is installed on the side plate of the frame and the guide bearing is mounted on the upper dewatering beam and / or the lower dewatering beam. Installed and the guide bearing interacts with the guide bar and moves along the guide bar.

In the dewatering time extension dewatering device according to the present invention, the spherical knuckle bearing further includes a spherical knuckle bearing installed in the through hole of the support, and the spherical knuckle bearing has an inner hole and the spherical knuckle bearing is formed by the inner hole of the first end of the link rod. Will be impressed.

In the dehydration time extension dewatering device according to the present invention, the spherical knuckle bearing is installed in the through hole of the support via a platen, elastic washer or snap ring.

In the dehydration time extension dewatering device according to the present invention, the support further includes a support bush, the support bush being positioned between the lock adjusting member and the spherical knuckle bearing while being wound on the link rod.

In the dehydration time extension dewatering device according to the present invention, a protective cover or a bush is provided at the first end of the link rod, and the protective cover or the bush is provided with an outer circumferential surface of the first end of the link rod and the inner hole of the spherical knuckle bearing. It is installed between the main walls.

In the dehydration time extension dehydration apparatus according to the present invention, the dehydration device further includes a dehydration time extension member connected to the link rod.

In the dehydration time extension dewatering device according to the present invention, it further comprises a working washer, which is installed on the link rod and located above the lock adjustment member.

In the dehydration time extension dewatering device according to the invention, the dehydration time extension member is a pressing spring assembly and the pressing spring assembly includes a pressing spring, an upper pressing spring stand and the upper pressing spring stand is installed on the link rod and The pressing spring is installed and maintained between the upper pressing spring stand and the support.

In the dehydration time extension dewatering device according to the present invention, the pressing spring assembly further comprises a lower spring stand and the lower pressing spring stand is manufactured or fixedly connected to or integral with the support and the pressing spring is connected to the upper pressing spring stand. It is installed and maintained between the lower pressing spring stand.

In the dehydration time extension dewatering device according to the invention, the lower pressing spring stand is made of a fixed connection or integral with the support.

In the dehydration time extension dewatering device according to the invention, the lower pressing spring stand is made of a fixed connection or integral with the protective cover installed on the first end of the link rod and the protective cover of the first end of the link rod It is installed between the outer circumferential surface and the inner wall circumferential wall of the spherical knuckle bearing.

In the dehydration time extension dewatering apparatus according to the present invention, a dewatering sponge is provided in each of the upper and lower dewatering beams.

In the dewatering time extension dewatering device according to the invention, the support is made integrally with the upper dewatering beam or is decomposably connected by welding or by means of a connector.

The dehydration time extension dewatering device according to the present invention is to replace the conventional complete restraint assembly by using an incomplete restraint drive device in the vertical direction of the upper dewatering beam to extend the compression dehydration time by generating a spare stroke in the compression dewatering process. It can squeeze out the moisture generated in the seaweed that has been floated in the seaweed herbicide process to the maximum and can shorten the drying time of the seaweed that is realized, thus achieving the technical effect of energy saving and consumption reduction. In addition, since the dehydration time extension dehydration apparatus according to the present invention employs an adjustable member, the dehydration time extension dehydration apparatus can be controlled together with the dehydration strength and the dehydration time, thereby widening the application range of the dehydration apparatus. In addition, since the extension of the guide member is greatly reduced the movement resistance of the dewatering beam, and thus can reduce the power consumption is advantageous in reducing the production cost and energy consumption.

Fig. 1A is a structural diagram of a conventional floating seaweed dewatering device, in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are separated from each other.
Fig. 1B is a structural diagram of a conventional floated dehydration device, and the figure shows a state in which the water in the steamed seaweed is started to be squeezed out by the dehydration sponge of the upper dewatering beam and the dehydration sponge of the lower dewatering beam.
FIG. 2A is a structural diagram of a floating dehydrating device according to a first embodiment of the present invention, and FIG. 2 shows a state in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are separated from each other.
FIG. 2A 'is a side view of FIG. 2A and is a projection view seen from the end direction of the upper and lower dehydration beams.
FIG. 2B is a structural diagram of a floating dehydrating device according to the first embodiment of the present invention, and FIG. 2 shows a state in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam move in opposite directions.
FIG. 2B 'is a side view of FIG. 2B.
Figure 2c is a structural diagram of the floating dehydration apparatus according to the first embodiment of the present invention, in the figure, the dehydration sponge of the upper dewatering beam and the dehydration sponge of the lower dewatering beam is bonded to each other by opposing movement to the moisture in the steaming It marks where to start squeezing.
Figure 2c 'is a side view of Figure 2c.
3 is an enlarged view of a portion of part I of FIG. 2A.
4 is an enlarged view of a portion II of 2a.
5A is a structural diagram of a floating dehydration apparatus according to a second embodiment of the present invention, and FIG. 5 shows a state in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are separated from each other.
Fig. 5A 'is a side view of Fig. 5A, and is a projection view seen from the end direction of the upper and lower dehydration beams.
FIG. 5B is a structural diagram of a floating dehydrating device according to a second embodiment of the present invention, and FIG. 5 shows a state in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam move oppositely.
Fig. 5B 'is a side view of Fig. 5B.
5C is a structural diagram of a floating dehydrating device according to a second embodiment of the present invention, in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are bonded to each other by opposing movement. It marks where to start squeezing.
Figure 5c 'is a side view of Figure 5c.
FIG. 6 is an enlarged view of a portion I of FIG. 5A.
FIG. 7 is an enlarged view of a portion II of FIG. 5A.
FIG. 8A is a structural diagram of a floating dehydrating device according to a third embodiment of the present invention, and FIG. 8 shows a state in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are separated from each other.
Fig. 8A 'is a side view of Fig. 8A, and is a projection view seen from the end direction of the upper and lower dehydration beams.
FIG. 8B is a structural diagram of a floating dehydrating device according to a third exemplary embodiment of the present invention, in which the dewatering sponge of the upper dewatering beam and the dewatering sponge of the lower dewatering beam are opposed to each other.
8B 'is a side view of FIG. 8B.
FIG. 8C is a structural diagram of a floated dehydration device according to a third embodiment of the present invention. It marks where to start squeezing.
8C 'is a side view of FIG. 8C.
9 is an enlarged view of a portion I of FIG. 8A.

<First Example>

As shown in Fig. 2, the figure shows a first embodiment of the present invention. The dehydration time extension floating dehydration device of this embodiment replaces the complete restraint assembly with an incomplete restraint assembly, and at the same time, there is a margin of stroke in the dewatering operation, and at the same time, the sponge is dehydrated by using the weight of the upper dewatering beam. Therefore, it is possible to extend the dehydration time, to squeeze out the moisture generated in the seaweed that has been floated in the seaweed herbicide process to the maximum, and to shorten the drying time of the floating seaweed to achieve the technical effect of energy saving and consumption reduction. The apparatus of this embodiment changes the mutual restraint relationship of the conventional dehydration apparatus. That is, the stem bearing 7 located at the upper end of the one tension bar 8 is omitted, and the one end bar 8 is replaced with the link rod 16 having the smooth upper edge, and the support hole at the end of the upper dehydration beam 1 is replaced. Alternatively, the bearing stand 12 is expanded, and the spherical knuckle bearing 13 is inserted in the support or bearing stand 12, and the upper end or the first end of the link rod 16 escapes the inner hole of the spherical knuckle bearing 13. The lower end or the second end of the link rod 16 may be connected to the eccentric wheel shaft 10 of the eccentric cam 11 via, for example, a knuckle bearing, and the eccentric cam 10 may be a transmission shaft installed in the frame. (Not shown). The eccentric wheel shaft 10 may be installed in the eccentric cam 11 while being manufactured integrally with the eccentric cam 11 or separately. A lifting lug is provided at the bottom of the lower dewatering beam 4 and a working bearing 9 is provided at the lifting lug. When the eccentric cam 11 is driven, the action bearing 9 is moved along the up-down direction by the pushing-up action of the rotating eccentric cam 11. At the same time, the eccentric wheel shaft 10 of the eccentric cam rotates in accordance with the rotation of the eccentric cam to move the link rod 16 up and down. The lock nut 15 is installed on the link rod 16 and is located below the spherical knuckle bearing 13. A brace bush 14 is provided between the spherical knuckle bearing 13 and the lock nut 15 and the brace bush 14 is mounted on the link rod 16. As a result, when the link rod 16 is driven by the lower eccentric wheel shaft 10 and moved downward, the link rod 16 can slide the inside of the spherical knuckle bearing 13. On the contrary, when the link rod 16 is moved upward, the lock nut 15 pushes up the upper dewatering beam 1 through the brace bush 14, the spherical knuckle bearing 13, and the support 12. Let it work In addition, by adjusting the upper and lower positions on the link rod 16 of the lock nut 15 can serve as a dehydration time adjustment.

Hereinafter, a first preferred embodiment of the dehydration time extension dehydration apparatus according to the present invention will be described in detail with reference to FIGS. 2A to 4.

As shown in Figure 2a, Figure 2a ', Figure 2b, Figure 2b', Figure 2c, Figure 2c ', Figure 3, and Figure 4, the dewatering device for extended dehydration time according to the present invention is mainly an upper dehydration beam ( 1), the lower dewatering beam (4), spherical knuckle bearing (13), link rod (16), eccentric wheel shaft (10), eccentric cam (11), the upper and lower dehydration beams (1, 4) of the frame When installed and operated, they can move in opposite or orientation along the vertical direction. An upper dewatering sponge 2 is provided on the upper dewatering beam 1, and a lower dewatering sponge 3 is provided on the lower dewatering beam 4. At the end of the upper dewatering beam 1, a support or a bearing stand 12 is added, and a spherical knuckle bearing 13 is fitted in the bearing stand 12. The knuckle bearing 13 is held in the bearing stand 12 via, for example, an elastic washer or a snap ring, and the upper end or the first end of the link rod 16 exits the inner hole of the spherical knuckle bearing 13 and the link rod ( The lock nut 15 is provided in the lower part of the spherical knuckle bearing 13 on 16, and the brace bush 14 is provided between the spherical knuckle bearing 13 and the lock nut 15. As shown in FIG. Therefore, when the link rod 16 is driven by the lower eccentric wheel shaft 10 and moved downward, the link rod 16 can slide the inside of the spherical knuckle bearing 13. On the contrary, when the link rod 16 is moved upward, the lock nut 15 pushes up the upper dewatering beam 1 through the brace bush 14, the spherical knuckle bearing 13, and the support 12. Let it work In addition, in order to increase the stability and accuracy when moving along the vertical direction of the upper and lower dehydration beams (1, 4), the floating dehydration time extension dewatering device according to the present invention is the upper dehydration beam (1) and the lower dehydration beam (4) Guide bearings (19, 20) are further expanded. The guide bearings 19 and 20 serve as position limitations and guides by interaction with the guide bars 18 installed in the frame side plate 5, and the upper and lower dehydration beams can only move up and down. And by the rotation of the guide bearings (19, 20) can reduce the running resistance of the upper and lower dehydration beam, can reduce the wear between the members and can reduce the power consumption. It should be explained here that the guide bearings may be used in combination or may be used alone. That is, only the guide bearing 19 may be provided or only the guide bearing 20 may be provided. The guide bearing 19 or 20 may be installed only in one of the dewatering beams, for example, the guide bearing 19 or 20 is installed only in the upper dewatering beam, or the guide bearing 19 or only in the lower dewatering beam. Install (20). In addition, the lower dewatering beam 4 is provided with at least one position limiting bolt 17, which is used to limit the downward movement of the upper dewatering beam 1. Naturally, the position limiting bolt may be replaced with another position limiting member, or the shape, size, structure, and position of the position limiting member may be adjusted based on actual demand and specific application conditions. For example, you may install this in a side plate.

The device replaces a complete restraint assembly with an incomplete restraint assembly, which results in an extra stroke in the dewatering process, thus realizing the purpose of extending the dewatering time. Below, the operation principle and operation of the apparatus will be described in detail.

When the eccentric wheel shaft 10 is rotated to top dead center, as shown in Fig. 2A, this tends to be a downward motion. At this time, the eccentric wheel shaft (10) makes the downward movement by linking the link rod 16, but the upper dewatering beam (1) by the self-weighting action to push down as the link rod 16 descends. At the same time, the eccentric cam 11 pushes up the action bearing 9 so as to move upward by interlocking the lower dewatering beam 4. As a result, the upper and lower dehydration beams 1 and 4 move oppositely as shown in Fig. 2B. When the upper and lower dewatering beams 1 and 4 are moved to the position where the upper and lower dewatering sponges 2 and 3 are bonded to each other, the upper dewatering beam 1 is applied to the upper and lower dewatering sponges 2 and 3 by its own weight. The dehydration sponge is compressed and dehydrated by pressing the dehydrated sponge in the contracted state. When the bottom of the upper dehydration beam 1 moves and joins with the position limiting bolt 17, the upper dehydration beam 1 stops moving, but at this time, the link rod 16 has the eccentric wheel shaft 10 of the eccentric cam 11 Continue down to the bottom dead center. In this process, the upper outer edge of the link rod 16 slides the inner hole of the spherical knuckle bearing 13, and the support bush 14 gradually falls from the spherical knuckle bearing 13, thereby generating a distance, that is, a stroke. When the eccentric cam 11 continues to rotate, the link rod 16 starts to lift, but at this time, the upper dewatering beam 1 does not immediately lift, but the bracing bush 14 moves upward and the spherical knuckle bearing 13 The upper dewatering beam 1 first starts to be lifted by the lifting of the bearing stand 12 as it comes into contact with the lower plane of the plane. Therefore, in the process from the bottom of the upper dewatering beam 1 to the contacting and holding the position limiting bolt 17 to the detachment, the apparatus is in a dewatering state all the time, thereby extending the effective dehydration time.

The operation manner of the lower dewatering beam 4 is the same as in the prior art, and the lifting operation of the lower dewatering beam 4 is driven by the eccentric cam 11 while descending and returning by its own weight. Duplicate explanations are omitted here.

The dehydration strength and the dehydration time length can be realized by adjusting the height of the position limiting bolt 17 and the position of the lock nut 15. Specifically, the height of the position limiting bolt 17 fixed to the lower dewatering beam 4 is adjustable and the size of the amount of compression of the sponge can be adjusted by adjusting the height of the position limiting bolt. That is, the size of the dehydration strength can be controlled. The position of the lock nut 15 fixed to the link rod 16 is also adjustable. By adjusting the high and low position of the lock nut 15, the timing at which the upper dewatering beam 1 is pushed up can be changed. Adjusting upward, the dehydration time is shortened because the upper dehydration beam 1 is lifted up quickly. Adjusting downward, the dehydration time is extended because the upper dehydration beam 1 is lifted up with delay. This realizes control of the dehydration time.

When the link rod 16 is driven by the eccentric wheel shaft 10 and moves up and down, the link rod 16 also rotates around the eccentric wheel shaft 10 and the knuckle of the spherical knuckle bearing 13 is also the link rod 16. It is driven in the rotational shape and at the same time the link rod is able to slide the inner hole of the spherical knuckle bearing (13). In addition, since the link rod 16 tries to move the inner hole of the spherical knuckle bearing 13, some friction may occur between the link rod 16 and the inner hole of the bearing 13 during the operation process. In order to prevent wear of the link rod 16, a bush or a protective cover (for example, a copper cover) or a space is provided at a portion of the spherical knuckle bearing 13 outside the link rod 16 to interact with the inner hole. You may provide the bar-shaped member (not shown) arrange | positioned.

It should be explained here that the spherical bearing 13 may be omitted and only the bearing stand may be suspended based on actual application conditions. It is only necessary to ensure the normal operation of the link rod 16 by matching the size of the bearing stand hole with the support bush 14, but in this situation, the spherical bearing is not already installed in the bearing stand. It is equivalent to a support that is installed on the link rod and used to move the link rod to the upper dehydration beam. It is also conceivable to omit the brace bush 14. At this time, the size of the inner hole of the bearing stand (or support) only needs to be matched with the lock nut 15 to ensure the normal operation of the link rod.

In addition, the support or bearing stand 12 at the end of the upper dewatering beam 1 may be manufactured integrally with the upper dewatering beam, or by a fixed connection method such as welding or riveting, and a detachable method such as screw connection or bolt. You may connect to the edge part of the upper dehydration beam 1.

In addition, when the weight of the upper dewatering beam (1) is insufficient, by adding weight or weight on the upper dewatering beam (1) increases the weight of the upper dewatering beam, thereby having the necessary watering and dewatering ability.

<Second Embodiment>

As shown in Figs. 5A to 7, Fig. 5 shows a second embodiment of the present invention. The dehydration time extension floated dehydration device of this embodiment replaces the complete restraint assembly with an incomplete restraint assembly, while generating a dehydration time for the dehydration operation by using the dehydration time extension member. Make appropriate and effective control of In this embodiment, the dehydration time extension member is further extended based on the conventional dehydration apparatus. Among these, the dehydration time extension member is a press spring assembly, and the press spring assembly mainly includes a press spring 212, an upper press spring stand 213 ', and a lower press spring stand 213. The upper and lower press spring stands are press springs ( 212) to provide support. In order to increase the stability and accuracy when moving in the vertical direction of the upper and lower dehydration beams (1, 4), the device is further extended with a guide member, the guide member is mainly the upper and lower dehydration beam guide bar 217, the guide bearing ( 218, 219). In addition, one bracket or support 220 may be fixed to the upper dewatering beam 1 in order to have sufficient support strength in the lower spring stand 213. The pressing spring stand 213 may be fixed to the bracket 220, whereby the lower pressing spring stand 213 can be more stably operated. Naturally, since this bracket belongs to the selectable arrangement, the bracket can be omitted under the premise that the pressing spring stand 213 can operate stably. In addition, the floating seaweed dehydration device according to the present invention to further control the dehydration time is added to the lock nut 215 to the link rod 208, the lock nut 215 is not only to lock the role of dehydration time It can also play a role. In addition, the floating dewatering device according to the present invention is further installed one seat or washer between the lower spring stand 213 and the lock nut 215.

5A to 7, a dewatering dewatering device according to a second embodiment of the present invention will be described in detail.

As shown in Figures 5a to 5c, 6 and 7, the floated dehydration apparatus according to the second embodiment of the present invention is mainly the upper dewatering beam (1), lower dewatering beam (4), dehydration time extension member And a link rod 208, an eccentric wheel shaft 210, and an eccentric cam 211. In this embodiment, the dehydration time extension member is a push spring assembly, and the upper and lower dehydration beams 1 and 4 are installed in the frame. In operation they can move in opposite or orientation along the up and down direction. An upper dewatering sponge 2 is provided on the upper dewatering beam 1, and a lower dewatering sponge 3 is provided on the lower dewatering beam 4. The pressing spring assembly mainly includes a working spring or pressing spring 212, an upper pressing spring stand 213 ′, a lower pressing spring stand 213 and the lower pressing spring stand 213 is mounted to the upper dewatering beam 1 and Each of the upper and lower pressing spring stands 213 'and 213 is provided with one through hole to allow the link rod 208 to pass therethrough. The action spring or the pressing spring 212 is abutted on the link rod 208 while being supported by the upper and lower pressing spring stands 213 ', 213. At the upper end of 208, a lock nut 215 'which interacts with the upper press spring stand is attenuated, and a washer 214 is provided below the press spring stand 213'. A lock nut 215 is provided below the washer 214, and the push spring may be held on the link rod 208 using the lock nuts 215 ′ and 215. The lock nut 215 can not only hold the press spring 212 on the link rod but also adjust the position of the nut on the link rod 208 to realize effective control of the dehydration time. The pressing spring stand 213 is fixed to the upper dewatering beam, but the pressing spring stand 213 may be directly fixed to the upper dehydrating beam 1, or the pressing spring stand 213 is disposed through one bracket or support 220. May be fixed to the upper dewatering beam. The pressing spring stand 213 and the support 220 of the upper dewatering beam are provided with a through hole for allowing the link rod 208 to slide while allowing the link rod to be restrained when operated. No interference. In addition, in order to increase the stability and accuracy when moving in the vertical direction of the upper and lower dehydration beams (1, 4), the floating dewatering device according to an embodiment of the present invention is provided in the upper dehydration beam (1) and the lower dehydration beam (4) The guide bearings 219 and 218 are further expanded. The guide bearings 219 and 218 act as position limitations and guides by interaction with the guide bar 217 fixed to the frame side plate 5, and the upper and lower dehydration beams can only move up and down. The running resistance of the upper and lower dehydration beams can be reduced by the rotation of the guide bearings 218 and 219 and the energy consumption can be reduced. It should be noted that only the guide bearings 218 or 219 may be provided or the guide bearings 218 or 219 may be provided only for the upper dewatering beam or the lower dewatering beam. In addition, the lower dewatering beam 4 is further provided with at least one position limiting bolt 216, which is used to limit the downward movement stroke of the upper dewatering beam 1. Naturally, the position limiting bolt may be replaced with another position limiting member, or the shape, size, structure, and position of the position limiting member may be adjusted based on actual demand and specific application conditions.

In this embodiment, the drive to the upper dewatering beam 1 is realized by replacing the conventional rigid assembly with a flexible assembly such as a pressing spring. Below, the operation principle is explained in full detail.

When the eccentric wheel shaft 10 is rotated to top dead center, as shown in Fig. 5A, this tends to be a downward motion. At this time, the eccentric wheel shaft 10 moves down the upper dewatering beam 1 by the link rod 208 and the pressing spring 212. At this time, the action spring 212 starts to compress, and at the same time, the eccentric cam 11 pushes up the action bearing 9 to move the lower dewatering beam 4 in conjunction with it. As a result, the upper and lower dehydration beams 1 and 4 move oppositely as shown in Fig. 5B. When the bottom of the upper dewatering beam 1 moves and joins the position limiting bolt 216, as shown in Fig. 5C, the upper dewatering beam 1 stops motion. At this time, the lower dewatering beam 4 moves to the position where the lower dewatering sponge 3 is in contact with or bonded to the lower surface of the foot 6, and the dewatering sponges 2, 3 on the upper and lower dewatering beams 1, 4 Compression and dehydration are performed on the floating steam on the foot, and at the same time, the link rod 208 is continuously lowered. In this process, the action spring is in a compressed state all the way until the eccentric wheel shaft 10 of the eccentric cam 11 reaches the bottom dead center. As the eccentric cam 11 continues to rotate, the link rod 208 starts to lift up and as the link rod 208 lifts up, the action spring 212 also begins to increase gradually from the compressed state. At this time, the upper dewatering beam does not immediately lift up, but only when the working washer 214 starts pushing the bottom of the upper dewatering beam 1 for the first time. With the rotation of, it is gradually raised to the highest position shown in Fig. 5A. This completes one dehydration process. Subsequently, the eccentric wheel shaft 10 rotates continuously and enters the next dehydration process, thereby circulating and manipulating it. Therefore, according to the present embodiment, the dehydration sponge of the upper and lower dehydration beams performs compression dehydration all the time for the floating steam on the foot during the bottom surface of the upper dewatering beam 1 contacting and detaching the position limiting bolt 216. It is dehydrated all the time. This is to extend the dehydration time of the seaweed.

The operation of the lower dewatering beam 4 is the same as in the prior art, and the lifting operation of the lower dewatering beam 4 is driven by the eccentric cam 11 while descending and returning by its own weight. Duplicate explanations are omitted here.

The length of the dehydration strength and the dehydration time can be realized by adjusting the height of the position limiting bolt 216 and the position of the action washer 214 and the pressure of the pressing spring 212. Specifically, the height of the position limiting bolt 216 fixed to the lower dewatering beam 4 is adjustable and the size of the compressed amount of the sponge can be adjusted by adjusting the height of the position limiting bolt. That is, the size of the dehydration strength can be controlled. The position of the action washer 214 fixed to the link rod 208 is also adjustable. By adjusting the height position of the lock nut 215, the position on the link rod 208 of the action washer can be changed. Adjusting upwards will shorten the dehydration time, while adjusting downwards will extend the dehydration time. This realizes control of the dehydration time. The pressure of the pressing spring can be adjusted by the locknut 215 'and the upper pressing spring stand 213'.

In addition, the washer 214 may be manufactured integrally with the lock nut 215, or the washer 214 may be omitted and the lock nut 215 may be manufactured so that its diameter is larger than the diameter of the lower press spring. In this way, the same function can be realized.

<Third Example>

As shown in Figs. 8A to 9, the dewatering apparatus according to the third embodiment of the present invention is shown in the figure. The third embodiment is almost the same as the second embodiment, and the dehydration time extension floating dehydration device according to this embodiment also replaces the complete restraint assembly with an incomplete restraint assembly, while using a dehydration time extension member to allow stroke for the dehydration operation. The dehydration time of the steamed seaweeds is extended by generating a, and suitable and effective control of the dehydration time is performed. The difference from the first embodiment of this embodiment is mainly in the extension of the dehydration time extension member, and the difference in this embodiment from the second embodiment is mainly in the expansion of the spherical knuckle bearings. For the sake of simplicity and clarity, the following mainly describes in detail parts different from the first and second embodiments of the present embodiment, and overlapping detailed descriptions of the same parts as the first and second embodiments are omitted.

As shown in Figs. 8A to 9, the floating dewatering device according to the present embodiment mainly includes an upper dewatering beam 1, a lower dewatering beam 4, a spherical knuckle bearing 324, a bearing stand or a support 323. ), The link rod 308, the eccentric wheel shaft (10), the eccentric cam (11) and the dehydration time extension member in this embodiment, the dehydration time extension member is a pressing spring assembly of which the pressing spring assembly is mainly a pressing spring ( 312), an upper press spring stand 313 'and a lower press spring stand 321, wherein the upper and lower press spring stands are used to provide support to the press spring 312, and the upper and lower dehydration beams 1 and 4 When installed and operated in the frame, they can move in opposite or orientation along the vertical direction. An upper dewatering sponge 2 is provided on the upper dewatering beam 1, and a lower dewatering sponge 3 is provided on the lower dewatering beam 4. At the end of the upper dewatering beam 1, a support or a bearing stand 323 is installed, and a spherical knuckle bearing 324 is fitted in the bearing stand 323, and the spherical knuckle bearing 324 is provided by a platen 322. It is held within the bearing stand 323 and the platen 322 is also fixed to the bearing stand 323 by fasteners such as bolts, screws, etc. (of course the spherical knuckle bearing 324 is interposed between elastic washers or snap rings (not shown). May be held in the bearing stand 323). And the spherical knuckle bearing 324 is held in the bearing stand or the support 323 by the platen is also applicable to the first embodiment. The upper end or the first end of the link rod 308 exits the inner hole of the spherical knuckle bearing 324 and is positioned below the spherical knuckle bearing 324 on the link rod 308, and the lock nut 315 is installed. As a result, the link rod 308 can slide in the cavity of the spherical knuckle bearing 324 when the link rod 308 is driven by the lower eccentric wheel shaft 10 and moved downward. On the contrary, when the link rod 308 is moved upward, the lock nut 315 pushes the upper dewatering beam 1 through the spherical knuckle bearing 324 and the bearing stand 323 and the upper dewatering beam 1. Have the child move up. In addition, similar to the first and second embodiments, the dewatering time extension type dewatering device according to the present embodiment also has an upper portion in order to increase the stability and accuracy when moving in the vertical direction of the upper and lower dehydration beams 1 and 4. Guide bearings 318 and 319 are added to the dehydration beam 1 and the lower dehydration beam 4, and the guide bearings 318 and 319 are positioned by interaction with the guide bar 317 installed in the frame side plate 5; It acts as a restriction and guide, and the upper and lower dehydration beams can only move up and down. In addition, by the rotation of the guide bearings 318 and 319, the running resistance of the upper and lower dehydration beams can be reduced, the wear between the members can be reduced, and the power consumption can be reduced. Naturally, guide bearings may be used in combination or may be used alone. That is, only the guide bearing 318 may be provided or only the guide bearing 319 may be provided. The guide bearings 318 or 319 may be installed only in one of the dewatering beams. For example, the guide bearings 318 or 319 may be installed only in the upper dewatering beam or the guide bearings 318 or 319 only in the lower dewatering beam. . In addition, the lower dewatering beam 4 is provided with at least one position limiting bolt 316, which is used to limit the downward movement of the upper dewatering beam 1. Naturally, the position limiting bolt may be replaced with another position limiting member, or the shape, size, structure, and position of the position limiting member may be adjusted based on actual demand and specific application conditions. For example, you may install this in a side plate.

In addition, since the link rod 308 tries to move the inner hole of the spherical knuckle bearing 324, some friction may occur between the link rod 308 and the inner hole of the bearing 324 in the operation process. In order to prevent wear of the link rod 308, one bush or a protective cover (for example, a copper cover) or an interval is disposed at a portion of the link rod 308 that interacts with the inner hole of the bearing 324 outside the link rod 308. A bar-shaped member (not shown) may be provided. In this embodiment, the protective cover or bush is already manufactured integrally with the lower spring stand 321, but of course, the bush may be manufactured in a structure separate from the lower spring stand.

In this embodiment, like the first embodiment, a brace bush may be provided between the lock nut and the spherical knuckle bearing.

The difference between the present embodiment and the second embodiment is that the present embodiment mainly includes the addition of spherical knuckle bearings, and an additional protective cover in the interaction portion between the spherical knuckle bearing and the link rod. Since the operation method and operation principle of the present embodiment are almost the same as those of the second embodiment, detailed description thereof will be omitted here.

So far, the preferred embodiment of the dewatering device according to the present invention has been described in detail, but those skilled in the art can make various changes and modifications to the present invention based on the technical contents disclosed in the specification. Such modifications and variations are also within the protection scope of the present invention. For example, it is possible to replace the press spring assembly by employing a member having another similar function such as a cylinder, a motor, or the like. It is also possible for the guide member to adopt other structural forms such as guide rails or guide grooves. It is also possible for the brackets to adopt other types of structures, for example, each bracket or shaped support welded to the upper dewatering beam. Spherical knuckle bearings may also be replaced by employing a soft material such as rubber, spring assemblies or other similarly functional members.

Claims (20)

A dehydration time extension dewatering apparatus comprising: an upper dehydration beam, a lower dehydration beam, and a power mechanism for moving the upper dehydration beam and the lower dehydration beam in a direction opposing or oriented.
The power mechanism includes a link rod, and the dewatering device further includes a support, a lock adjusting member, and an upper dehydration beam position limiting member, wherein the support is installed at an end of the upper dewatering beam and has a hole therein. The first end extends through the through hole of the support, and moves within the through hole of the support within a predetermined range, and the lock adjustment member is installed on the link rod. The method according to claim 1,
The power mechanism further includes an eccentric cam and an eccentric wheel shaft installed in the eccentric cam, and the second end of the link rod is connected to the eccentric wheel shaft on the eccentric cam via a knuckle bearing. Device. The method according to claim 2,
The eccentric cam interacts with the action bearing installed in the lower dewatering beam and transmits power to the lower dewatering beam through the acting bearing so that the lower dewatering beam can be driven by the eccentric cam to move along the vertical direction. Dehydration time extension dewatering device characterized in that. The method according to any one of claims 1 to 3,
And the upper dewatering beam position limiting member is an adjustable position limiting bolt installed on the lower dewatering beam or on the side plate. The method according to any one of claims 1 to 4,
And the lock adjustment member is a lock adjustment nut. The method according to any one of claims 1 to 5,
And further comprising an upper dewatering beam and / or a lower dewatering beam guide member, wherein the guide member is used to guide the upper dewatering beam and / or the lower dewatering beam to move in a direction facing or mutually oriented. Extended dehydrator. The method of claim 6,
The guide member includes a guide bar and a guide bearing, the guide bar is installed on the side plate of the frame, the guide bearing is installed on the upper dewatering beam and / or the lower dewatering beam, and the guide bearing interacts with the guide bar. Meanwhile, a dehydration time extension dewatering device, characterized in that it moves along the guide bar. The method according to any one of claims 1 to 7,
And a spherical knuckle bearing installed in the through hole of the support, wherein the spherical knuckle bearing has an inner hole and the spherical knuckle bearing is wound on the first end of the link rod by the inner hole. Device. The method according to claim 8,
The spherical knuckle bearing is a dehydration time extension dewatering device, characterized in that installed in the through hole of the support via a platen, elastic washer or snap ring. The method according to claim 8 or 9,
And a bracing bush, wherein the bracing bush is positioned between the lock adjusting member and the spherical knuckle bearing and is mounted on the link rod. The method according to any one of claims 8 to 10,
The first end of the link rod is provided with a protective cover or bush, the protective cover or bush is installed between the outer peripheral surface of the first end of the link rod and the inner circumferential wall of the spherical knuckle bearing Decorative dehydrator. The method according to any one of claims 1 to 10,
The dehydration device is a dehydration time extension dewatering device further comprises a dehydration time extension member connected to the link rod. The method of claim 12,
And a washer, wherein the washer is mounted to the link rod and positioned above the lock adjustment member. The method according to claim 12 or 13,
The dehydration time extension member is a pressing spring assembly and the pressing spring assembly includes a pressing spring and an upper pressing spring stand, the upper pressing spring stand is installed on the link rod, and the pressing spring is between the upper pressing spring stand and the support. Dehydration time extended dehydration device, characterized in that the installation is maintained on. The method according to claim 14,
The pressing spring assembly further includes a lower spring stand, wherein the lower pressing spring stand is fixedly connected to or integrally manufactured with the support, and the pressing spring is installed and maintained between the upper pressing spring stand and the lower pressing spring stand. Dehydration time extension dewatering device characterized in that. The method of claim 11,
The dehydration device is a dehydration time extension dewatering device further comprises a dewatering time extension member installed on the link rod. The method according to claim 16,
The dehydration time extension member is a pressing spring assembly, the pressing spring assembly includes a pressing spring, an upper pressing spring stand, the upper pressing spring stand is installed on the link rod, and the pressing spring is an upper pressing spring stand and the supporter. Dehydration time extended dehydration device characterized in that the installation is maintained between. 18. The method of claim 17,
The pressing spring assembly further includes a lower spring stand, and the lower pressing spring stand is dehydration time extension dewatering device, characterized in that the fixed cover or manufactured integrally with the protective cover. The method according to any one of claims 1 to 18,
Dewatering time extended dewatering device, characterized in that the upper and lower dewatering beam is provided with a dewatering sponge, respectively. The method according to any one of claims 1 to 19,
And said support is made integrally with said upper dewatering beam or is decomposably connected by welding or by means of a connector.

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