阅读说明：本技术 巧克力浇注设备 (Chocolate pouring equipment ) 是由 杨东生 于 2020-11-23 设计创作，主要内容包括：本发明公开了一种巧克力浇注设备,包括框架以及固定在框架上部的浇注机构,所述框架下部具有用于输送模具的传动机构,所述传动机构具有沿所述模具的传输方向对称分布的两组第一传送带,所述两组第一传送带之间具有允许模具支撑机构做三维运动的空间。本发明移动模具的机构设置在巧克力浇注设备的下部,整机重心下移从而更加稳定；通过从传动机构中间向上托举的方式来启动模具的移动过程更加稳定可靠,移动时平稳而易于控制；模具定位后立即被向上托举进入浇注状态,传动机构按照设定好的速度即可实现相邻模具浇注的无缝衔接,充分利用时间和空间,提高生产效率。(The invention discloses chocolate pouring equipment which comprises a frame and a pouring mechanism fixed on the upper part of the frame, wherein the lower part of the frame is provided with a transmission mechanism for conveying a mould, the transmission mechanism is provided with two groups of first conveyor belts which are symmetrically distributed along the transmission direction of the mould, and a space for allowing a mould supporting mechanism to do three-dimensional motion is arranged between the two groups of first conveyor belts. The mechanism for moving the die is arranged at the lower part of the chocolate pouring equipment, and the gravity center of the whole machine moves downwards so as to be more stable; the moving process of the mold is started in a mode of lifting upwards from the middle of the transmission mechanism, so that the mold is more stable and reliable, and is stable and easy to control during moving; the mould is lifted upwards immediately after being positioned to enter a pouring state, the transmission mechanism can realize seamless connection of pouring of adjacent moulds according to a set speed, time and space are fully utilized, and production efficiency is improved.)

1. Chocolate pouring equipment, including the frame and fix the pouring mechanism on frame upper portion, its characterized in that: the lower part of the frame is provided with a transmission mechanism for conveying the die, the transmission mechanism is provided with two groups of first conveyor belts which are symmetrically distributed along the transmission direction of the die, and a space for allowing the die supporting mechanism to do three-dimensional motion is arranged between the two groups of first conveyor belts.

2. The chocolate pouring apparatus of claim 1, wherein: the mould supporting mechanism is positioned between the two groups of first conveyor belts and is controlled to move in three dimensions by the mould driving mechanism.

3. The chocolate pouring apparatus of claim 2, wherein: the mould supporting mechanism is fixedly connected with the mould driving mechanism.

4. The chocolate pouring apparatus of claim 2, wherein: the mould supporting mechanism is connected with the mould driving mechanism through a connecting mechanism.

5. The chocolate pouring apparatus of claim 4, wherein: the die driving mechanism comprises a first shaft driving part, a second shaft driving part and a third shaft driving part which are used for realizing three-dimensional motion control.

6. The chocolate pouring apparatus of claim 5, wherein: the first shaft driving piece is fixedly connected with the connecting mechanism, the fixed part of the second shaft driving piece is fixedly connected with the frame, and the third shaft driving piece is respectively connected with the first shaft driving piece and the second shaft driving piece in a sliding mode.

7. The chocolate pouring apparatus of claim 6, wherein: the mold supporting mechanism comprises a supporting platform and a supporting driving piece located below the supporting platform.

8. The chocolate pouring apparatus of claim 4, wherein: the transmission mechanism further comprises a second conveyor belt positioned below the first conveyor belt, and the transmission direction of the second conveyor belt is opposite to that of the first conveyor belt.

9. The chocolate pouring apparatus of claim 8, wherein: the die driving mechanism is positioned on the side surface of the transmission mechanism.

10. Chocolate pouring device according to any of the claims 1 to 9, characterized in that: and mould positioning mechanisms are arranged on two sides of the transmission mechanism.

Technical Field

The invention relates to chocolate pouring equipment.

Background

In order to meet the requirements of multilayer pouring, decorating or other modeling of chocolate, the conventional chocolate pouring equipment is mainly divided into two types, wherein one type is that a pouring head is fixedly arranged and is matched with a mechanical arm or a frame clamping mechanism to carry a chocolate mould, and most of the conventional chocolate pouring machines adopt the structure; another is that the casting head is movable relative to the frame, and a few chocolate casting machines employ this type of construction.

The Chinese patent application with publication number CN111869775A discloses a preparation method of dark chocolate, which adopts pouring equipment comprising a filling device fixed on an installation rack, wherein a first conveyor belt on the installation rack is used for driving a mould plate to move to the lower part of the filling device for pouring, and a connecting frame and a fixing plate for grabbing the mould plate below are arranged at two sides of a hopper above the filling device, namely the first pouring equipment; chinese patent application publication No. CN106578272A discloses a chocolate pouring device, in which a pouring head is connected to other structures, especially a material conveying portion, through a flexible hose, so that the pouring head can move lightly, i.e., the second pouring device. In addition, chinese utility model patent with publication number CN201491663U discloses a moving device that can drive the pouring head to realize three-axis movement, so that the aforementioned needs can be basically satisfied.

However, the above solutions all have the drawbacks that are difficult to overcome: the first pouring head is fixed, the first conveying belt must stop moving when the mold plates are grabbed and carried, the next mold plate can move to the position below the pouring head after the previous mold plate is poured, the first conveying belt stops moving again, the operation cycle is greatly prolonged, and meanwhile, the mode that the mold plates are clamped by the frame can not only increase the probability of misoperation, but also prolong the operation cycle, and the production efficiency is low; the second way of moving the pouring head is limited by the hose, when the moving distance is long, the temperature of the chocolate mass is difficult to control, and the product quality is not stable. Moreover, the two schemes have a common defect that the mechanisms for grabbing and moving the pouring head are positioned at the upper half part of the whole machine, so that the gravity center of the whole machine is higher, and the stability of the equipment is poor.

Disclosure of Invention

The invention aims to solve the technical problem of providing chocolate pouring equipment with a mould supporting mechanism so as to overcome the defects of high gravity center, difficult temperature control and low production efficiency of the whole machine in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the chocolate pouring equipment comprises a frame and a pouring mechanism fixed on the upper portion of the frame, wherein a transmission mechanism used for conveying a mold is arranged on the lower portion of the frame, the transmission mechanism is provided with two groups of first conveyor belts which are symmetrically distributed along the transmission direction of the mold, and a space allowing the mold supporting mechanism to do three-dimensional motion is formed between the two groups of first conveyor belts.

Further, the mould supporting mechanism is positioned between the two groups of first conveyor belts, and the mould driving mechanism controls the three-dimensional movement.

Further, the mold supporting mechanism is fixedly connected with the mold driving mechanism.

Further, the mould supporting mechanism is connected with the mould driving mechanism through a connecting mechanism.

Further, the die driving mechanism comprises a first shaft driving part, a second shaft driving part and a third shaft driving part which are used for realizing three-dimensional motion control.

Further, the first shaft driving piece is fixedly connected with the connecting mechanism, the fixing part of the second shaft driving piece is fixedly connected with the frame, and the third shaft driving piece is respectively connected with the first shaft driving piece and the second shaft driving piece in a sliding mode.

Further, the mold supporting mechanism comprises a supporting platform and a supporting driving member located below the supporting platform.

Further, the transmission mechanism further comprises a second conveyor belt located below the first conveyor belt, and the transmission direction of the second conveyor belt is opposite to that of the first conveyor belt.

Further, the die driving mechanism is located on the side of the transmission mechanism.

Furthermore, mould positioning mechanisms are arranged on two sides of the transmission mechanism.

Compared with the prior art, the invention has the advantages that the mechanism for moving the die is arranged at the lower part of the chocolate pouring equipment, and the gravity center of the whole machine moves downwards so as to be more stable; the moving process of the mold is started in a mode of lifting upwards from the middle of the transmission mechanism, so that the mold is more stable and reliable, and is stable and easy to control during moving; the mould is lifted upwards immediately after being positioned to enter a pouring state, the transmission mechanism can realize seamless connection of pouring of adjacent moulds according to a set speed, time and space are fully utilized, and production efficiency is improved.

Drawings

FIG. 1 is a schematic sectional view of a chocolate casting apparatus according to the present invention;

FIG. 2 is a schematic sectional view of the chocolate pouring apparatus of the present invention along the moving direction of the mold;

FIG. 3 is a schematic top view of the chocolate casting apparatus of the present invention with the casting mechanism removed;

FIG. 4 is a schematic cross-sectional view of the mold driving mechanism and the mold supporting mechanism shown in FIG. 1;

FIG. 5 is a schematic view of a part of the structure of a chocolate casting apparatus according to the present invention.

Detailed Description

The invention is described in further detail below with reference to the accompanying examples. The movement of the pouring mechanism, various driving mechanisms, positioning mechanisms, transmission mechanisms and other mechanisms of the pouring equipment is controlled by the control system according to the setting.

Referring to fig. 1 to 5, the chocolate casting apparatus of the present invention includes a frame 800, a casting mechanism 200 fixed to an upper portion of the frame 800, a mold driving mechanism 300 fixedly connected to a lower portion of the frame 800, and a driving mechanism 500 for conveying the mold 100 located at a lower portion of the frame 800. The transmission mechanism 500 has two sets of first conveyor belts 501 symmetrically distributed along the transmission direction, the two sets of first conveyor belts 501 extend along the transmission direction of the mold 100 and move synchronously, a space allowing the mold supporting mechanism 700 to make three-dimensional motion is provided between the two sets of first conveyor belts 501, the mold supporting mechanism 700 is located between the two sets of first conveyor belts 501 and controlled by the mold driving mechanism 300 to make three-dimensional motion, and the mold supporting mechanism 700 supports the mold 100 from below and drives the mold 100 to make three-dimensional motion. In one embodiment, the mold support mechanism 700 is fixedly coupled to the mold drive mechanism 300; when the mold driving mechanism 300 is not located below the mold supporting mechanism 700, the mold supporting mechanism 700 is connected to the mold driving mechanism 300 through a connecting mechanism 360, and in one embodiment, the connecting mechanism 360 is a connecting plate.

In one embodiment, the mold driving mechanism 300 includes an X-axis driving unit 320, a Y-axis driving unit 310, and a Z-axis driving unit 330, which are driven by an X-axis motor 321, a Y-axis motor 311, and a Z-axis motor 331 respectively to reciprocate axially. In one embodiment, the Y-axis driving member 310 is fixedly connected to the connecting mechanism 360, the Y-axis driving member 310 is slidably connected to the X-axis driving member 320 and can perform Y-axis reciprocating motion with respect to the X-axis driving member 320, the X-axis driving member 320 is slidably connected to the Z-axis driving member 330 and can perform X-axis reciprocating motion with respect to the Z-axis driving member 330, a fixed portion of the Z-axis driving member 330 is fixedly connected to the frame 800, and a movable portion of the Z-axis driving member 330 can perform Z-axis reciprocating motion with respect to the frame 800. In one embodiment, the X-axis driving element 320 and the Z-axis driving element 330 are slidably connected through a connecting bracket 350, specifically, the movable portion of the Z-axis driving element 330 is fixedly connected with the connecting bracket 350, and the connecting bracket 350 is slidably connected with the X-axis driving element 320.

In some inferior embodiments, one or both of the drives may be reduced, e.g., only the X-axis drive 320 and the Z-axis drive 310 remain, and accordingly, the range of motion of the mold 100 is limited. In other embodiments, a first shaft driving member of the three shaft driving members is fixedly connected to the connecting mechanism 360, a fixing portion of the second shaft driving member is fixedly connected to the frame 800, and a third shaft driving member is slidably connected to the first shaft driving member and the second shaft driving member, respectively. In other embodiments, the mold driving mechanism 300 may be other mechanisms capable of three-dimensional motion, and is not limited to the three-axis driving mechanism disclosed above.

In one embodiment, the mold supporting mechanism 700 includes a supporting platform 710, a supporting driving member 720 located below the supporting platform 710, and a positioning member 730 located on the supporting platform 710, the supporting platform 710 is used for supporting the mold 100 from below, and the positioning member 730 on the supporting platform 710 can match with the positioning fitting on the mold 100 to accurately position the mold 100 on the supporting platform 710. In one embodiment, the positioning member 730 and the positioning accessory are both magnets. The support driving member 720 moves in the same direction as the Z-axis driving member 330, i.e., vertically moves up and down, and the support driving member 720 is used for making up for the insufficient stroke of the Z-axis driving member 330, and in one embodiment, the support driving member 720 is a cylinder. When the mold driving mechanism 300 is located below the mold supporting mechanism 700, the mold driving mechanism 300 is directly connected to the mold supporting mechanism 700, and in this case, the supporting driving member 720 may be omitted as needed, and the connecting mechanism 360 may also be omitted. In other embodiments, a first shaft driving member (Y-axis) of the three shaft driving members is fixedly connected to the supporting platform 710, a fixing portion of a second shaft driving member (Z-axis) is fixedly connected to the frame 800, and a third shaft driving member (X-axis) is slidably connected to the first shaft driving member and the second shaft driving member, respectively.

The vertical distance in the horizontal direction between the two sets of first conveyor belts 501 of the driving mechanism 500 should be larger than the maximum width of the mold supporting mechanism 700, i.e., to allow the mold supporting mechanism 700 to move upward from below the two sets of first conveyor belts 501 to a height higher than the mold 100 positioned on the first conveyor belts 501 without hindrance. The transmission mechanism 500 may further include two sets of second conveyor belts 502 located below the first conveyor belt 501, wherein the transmission direction of the second conveyor belts 502 is opposite to the transmission direction of the first conveyor belt 501, so as to form a double-layer circulation manner, and a linear production system is formed by matching with other equipment having the double-layer conveyor belts, and for the double-layer transmission equipment and the linear production system, reference may be made to another patent application (application number: 202010683413X) of the present applicant. When a double-layer conveyor belt is provided, the mold driving mechanism 300 is not disposed below the mold supporting mechanism 700, but is disposed at a side of the transmission mechanism 500 to avoid blocking the transmission of the second conveyor belt 502 located at the lower layer. Of course, if the rationality of the apparatus manufacturing cost, the apparatus height, and the center of gravity of the apparatus is not considered, it is also possible to place the mold driving mechanism 300 below the mold supporting mechanism 700 on the premise that the vertical distance between the first conveyor 501 and the second conveyor 502 is sufficiently large, as a poor solution.

In order to move the mold 100 to a position above the mold supporting mechanism 700, the mold positioning mechanisms 400 are symmetrically disposed on both sides of the transmission mechanism 500, and in one embodiment, the mold positioning mechanisms 400 include positioning cylinders 410 and positioning protrusions 420, which are configured to cooperate with positioning grooves (not shown) on the mold 100 to achieve positioning. In one embodiment, a sensor is also provided below the mold positioning mechanism 400 to signal the control system when the mold 100 reaches above the mold support mechanism 700. In other embodiments, the mold positioning mechanism 400 may also be other mechanical or electromagnetic positioning mechanisms that can temporarily position the mold 100 in the drive direction without impeding the movement of the mold 100 in the vertical direction.

The two sides of the transmission mechanism 500 are also provided with limiting mechanisms 600 to prevent the mold 100 on the transmission mechanism 500 from accidentally falling from the two sides of the transmission mechanism 500. In one embodiment, the stop mechanism 600 is a bar that extends in the drive direction of the mold 100.

In order to improve the working efficiency, the mold supporting mechanism 700 may be configured to lift more than one mold 100 at a time, for example, 2 molds 100 at a time, and 2 sets of corresponding pouring heads of the pouring mechanism 200 may be provided.

The basic working flow of the chocolate pouring equipment is as follows: the mold 100 is conveyed to the upper part of the mold supporting mechanism 700 through the first conveyor belt 501, the sensor detects the mold 100 and sends a signal to the control system, the control system controls the positioning cylinder 410 of the mold positioning mechanism 400 to push the positioning lug 420 to be close to and inserted into the positioning groove of the mold 100, so that the mold 100 is positioned above the mold supporting mechanism 700, the supporting platform 710 of the mold supporting mechanism 700 is driven by the mold driving mechanism 300 to lift and/or translate and align with the pouring head of the pouring mechanism 200, and the pouring mechanism 200 performs pouring under the control of the control system. During the pouring process, the transmission mechanism 500 does not stop transmission, after the previous mold/group mold 100 is poured, the mold supporting mechanism 700 returns to the original position, the poured mold 100 is placed back on the first conveyor belt 501 to continue to be conveyed forward, and meanwhile, the next mold/group mold 100 moves to the position above the mold supporting mechanism 700, and the aforementioned working procedure is repeated.