DE102010049969A1 - Hydraulically driven plastic processing machine, in particular injection molding machine - Google Patents

Abstract

A hydraulically driven plastic processing machine, in particular an injection molding machine, is described, means being provided with which heat can be extracted and supplied to the hydraulic oil. In order to cool the hydraulic oil during operation and to heat it up again before restarting, a heat store (18) is provided according to the invention, which can store heat extracted from the hydraulic oil and release it again to the hydraulic oil. A latent heat store is preferably provided, which is integrated directly into the hydraulic system, or an additional temperature control circuit is interposed between the hydraulic system and the heat store.

Description

The invention relates to a hydraulically driven plastic processing machine, in particular an injection molding machine, according to the preamble of claim 1.

On hydraulically driven injection molding machines, the hydraulic oil must be brought to a certain temperature level before operation of the injection molding machine, which is usually above the ambient temperature. For this purpose, energy is usually introduced into the hydraulic oil via the electrohydraulic drive of the hydraulic system and / or via electrical heating elements, which leads to the desired increase in temperature. The aforementioned first variant is disadvantageous in that the hydraulic oil is hydromechanically loaded, which can reduce its service life. The use of electrical heating elements is also associated with disadvantages, because this electrical energy must be expended, which is not productive.

Moreover, during operation of a hydraulically driven injection molding machine, heating of the hydraulic oil occurs. So that a given temperature level is not exceeded, the excess heat energy must be dissipated via a cooling system. It is particularly inefficient if this heat energy is released unused into the environment. Therefore, one strives to make even this waste heat still usable.

From the DE 10 2009 024 639 A1 It is known to supply the heat generated during operation of an injection molding machine waste heat, for example, from the hydraulic systems of the injection molding machine, a thermogenerator. The waste heat is thus converted into electrical energy and optionally cached in electrical storage devices such as accumulators or capacitors.

This cached electrical energy can be delivered to electrical consumers such as an electric heater and / or electric drives.

From the DE 10 2008 025 557 B4 an injection molding machine with a thermal compressor in the form of an adsorption refrigeration machine is known, this adsorption is cooled on the input side of a heated by the hydraulic oil cooling water and the output side of the cooling medium of a cooling circuit of the mold, so that the dissipated via the cooling water heat loss of the hydraulic oil by means of the thermal compressor Cooling of the mold is used.

From the EP 03 31 826 A1 is another known injection molding machine with hydraulically driven components, wherein the hydraulic oil is removed via a heat exchanger heat and this heat is used for other purposes such as for heating a room or for heating a mold.

Based on the aforementioned prior art, the present invention seeks to provide a hydraulically driven plastic processing machine, such as in particular an injection molding machine, wherein in a simple manner, the hydraulic oil can be cooled and heated alternately.

The solution of this object is achieved in a plastic processing machine of the generic type by the characterizing features of claim 1. Advantageous embodiments and further developments can be found in the dependent claims.

Characterized in that a heat storage is provided, which store the heat extracted from the hydraulic oil and can return to the hydraulic oil, the above-mentioned disadvantages are avoided. In particular, the cached heat can be reused at a later time for preheating the hydraulic oil, for example, after a production break. With this type of preheating, moreover, almost no operating noise is produced in comparison with the above. Preheating, in which energy is introduced via the hydromechanical drive in the hydraulic oil. In addition, the invention results in a reduction of the remaining necessary cooling power requirement of the machine and overall energy savings during heating and operation of the hydraulic machine. Since the preheating can be dispensed by introducing hydromechanical energy, the hydraulic oil is subject to reduced wear and its life is extended.

In addition, the energy balance compared to the above DE 10 2009 024 639 A1 better because the heat energy is not converted into another form of energy such as electrical energy.

In an advantageous embodiment, according to claim 2, a latent heat storage can be provided, for example, paraffin or a salt solution of suitable concentration can be used as a memory material of the latent heat storage (claim 3). About the concentration of the salt solution, the temperature level of the latent heat storage can be adjusted. Such inventively used latent heat storage are known per se. they work by utilizing the enthalpy of reversible thermodynamic state changes of the storage material, such as the solid-liquid phase transition. When charging the storage material, for example, the paraffins or salts are melted, taking a lot of heat energy (heat of fusion). Since this process is reversible, the storage material gives off exactly this amount of heat during solidification again.

To transfer the heat to the material of the heat accumulator and from this back to the hydraulic oil, for example (claim 4) may be provided a hydraulic line system, wherein parts of the hydraulic line system are passed through the heat storage. Alternatively, or optionally also in addition, a separate Temperiermittelkreislauf for the transmission of heat energy from the hydraulic oil to the heat accumulator and back are provided. This Temperiermittelkreislauf is so to speak interposed between the hydraulic oil circuit and the heat storage.

The invention will be described in more detail below with reference to an exemplary embodiment and with reference to the single FIGURE.

In the figure is schematically a Spritgießmaschine with a closing unit 1 and a plasticizing and injection unit 2 shown on a machine bed 3 are stored. In the example shown here is a two-plate clamping unit with a fixed platen 4 and one of these movable movable platen against 5 , The present on the two mold platens in operation mold halves of a mold are not shown for the sake of clarity. To move the movable platen are several, usually diagonally arranged traversing cylinder 6 intended. Between the platen columns run 7 for transmitting the closing force, in the present case by means of a closing force cylinder 8th can be generated. Usually there are four columns 7 arranged in the corner regions of the platens and for each column 7 is a closing force cylinder 8th assigned. For the sake of clarity, only the upper front pillar is present 7 is shown and seen. The plasticizing and injection unit here comprises one in a cylinder 9 rotary and linearly driven piebalds 10 , As a rotary drive, a hydraulic motor 11 and as a linear drive an injection cylinder 12 be provided. Such drives are known in the art and therefore need not be explained in detail. In addition to the hydraulically driven components of the injection molding machine shown here, other hydraulically driven components may be present such as a hydraulically actuated ejector or hydraulically operated core pulls in the mold. The hydraulically driven components are connected to a hydraulic system, which is essentially a hydraulic block 13 , a tank T and a pump P includes. For better clarity, there is only one supply line 14 and a derivative 15 for a drive component of the screw 10 shown. Of course, further supply and discharge lines are present and connect the hydraulic block 13 with the above hydraulically actuated components. The required hydraulic oil is sucked out of the tank by means of the pump P and via a supply line 16 the hydraulic block 13 fed. Oil returning from the hydraulic consumers can pass through the hydraulic block 13 and a derivative 17 to flow back into the tank T.

According to the invention is a heat storage 18 connected to the hydraulic system, in the present example, the supply line 16 through the heat storage 18 is passed, so that the storage material 19 is in direct contact with the hydraulic oil lines. In a preferred embodiment, the heat storage 18 designed as latent heat storage. As storage material 19 For example, paraffin or saline of appropriate concentration may be used. Of course, the heat storage can be integrated at another point in the hydraulic oil circuit. For example, the heat storage can be arranged in the return or in the derivative. Such an arrangement is hinted in the figure by the drain lines shown in dashed lines 17a and 17b and the only partially marked heat storage 18 ' shown. Opposite the arrangement in the inlet 16 the arrangement in the return or in the flow has the advantage that of the pump P, a lower pressure must be applied, because the oil in the inlet is not additionally through the heat storage 18 must be pumped. Furthermore, the pressure level of the oil flow in the return is significantly reduced, so that the heat accumulator can be constructed structurally simpler.

Furthermore, an additional temperature control between the hydraulic system and the heat accumulator can be provided, wherein on the one side of the temperature control circuit, a heat exchange with the hydraulic oil and on the other side of the temperature control takes place a heat exchange with the heat storage. It takes place in this case, therefore, no direct heat exchange between the hydraulic system and the heat storage. It is only important to temporarily store the heat to be removed from the hydraulic oil in the heat accumulator and return it to the hydraulic oil at a later time.

The hydraulic block 13 , the tank T and the pump P, possibly together with the heat storage 18 , in a housing in the area of the machine bed 3 be housed. The representation in the figure is not to be understood that the aforementioned components only below the machine bed 3 be arranged. In addition, a heat storage can be used for two or more machines.

With the present invention, the hydraulic oil can be cooled in operation in a simple and energy-efficient manner, so that it does not exceed a predetermined temperature level, and before a restart - when the hydraulic oil is cooled to ambient temperature - it can be heated to the desired operating temperature again ,

LIST OF REFERENCE NUMBERS

1

closing unit

2

Plasticizing and injection unit

3

machine bed

4

Fixed platen

5

Movable mold clamping plate

6

Verfahrzylinder

7

columns

8th

Closing force cylinder

9

plasticizing

10

slug

11

hydraulic motor

12

Injection cylinder

13

hydraulic block

14

supply

15

derivation

16

supply

17

derivation

17a

Derivation to the heat storage 18 '

17b

Derivation from the heat storage 18 '

18, 18 '

heat storage

19

storage material

P

pump

T

tank

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009024639 A1 [0004, 0011]
• DE 102008025557 B4 [0006]
• EP 0331826 A1 [0007]

Claims (5)

Hydraulically driven plastic processing machine, in particular injection molding machine, wherein means are provided with which the hydraulic oil heat can be withdrawn and supplied, characterized in that a heat storage ( 18 ) is provided, store the heat extracted from the hydraulic oil and can return to the hydraulic oil. Machine according to claim 1, characterized in that as heat storage ( 18 ) A latent heat storage is provided. Machine according to claim 2, characterized in that paraffin or a salt solution of suitable concentration as storage materials ( 19 ) of the latent heat storage ( 18 ) are provided. Machine according to one of the preceding claims, characterized in that a hydraulic line system is provided, wherein parts of the hydraulic line system ( 16 . 17a . 17b ) through the heat storage ( 18 ) are passed. Machine according to one of the preceding claims, characterized in that a separate Temperiermittelkreislauf is provided for the transmission of heat energy from the hydraulic oil to the heat accumulator and back.

Images